SU1724952A1 - Air lift - Google Patents

Abstract

The invention can be used in the energy, mining, metallurgical and other industries. The purpose of the invention is to increase the efficiency by reducing water loss and using the ejection effect. The airlift contains a lifting pipe 1 with slotted holes 8, in the lower part of which a mixer 2 is installed with an air duct 4 and suction nozzle 5, and in the upper part an air separator 3 and a casing 6 placed between the air separator 3 and pipe 1 communicated with the latter through the holes 8 located at its bottom, and executed

Description

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in the form of an open top of the glass, and the upper part of the glass is made conical with the formation of an annular nozzle 7 with a cut of the lifting pipe 1 and introduced into the air separator 3. The chamber 9 is formed by the lifting pipe 1 and the casing 6. , the excess air is withdrawn into chamber 9 and creates an additional leakage of the medium due to the ejector 7. Such an airlift design increases its efficiency by reducing water loss as a result of removing excess air from the airlift riser 1, without disturbing the flow pattern of the aero hydraulic mixture and using this excess air to eject the aero hydraulic mixture. 1 il.

The invention relates to the field of engineering, namely to air-lift devices for lifting liquids or pulp, and can be used in the energy, mining, metallurgical and other industries.

The aim of the invention is to increase efficiency by reducing water loss using the ejection effect.

The drawing shows the scheme of airlift, longitudinal section.

The airlift contains a lifting pipe 1 with slotted holes 8, in the lower part of which a mixer 2 with an air duct 4 and a suction pipe 5 is installed, and in the upper part an air separator 3 and a casing 6 placed between the air separator 3 and pipe 1 communicated with the latter through holes 8, located at its bottom, and made in the form of an open upward glass. The upper part of the barrel is tapered to form an annular nozzle 7 with a cut of the lifting pipe 1 and is introduced into the air separator 3. The lifting pipe 1 and the casing 6 form the chamber 9.

Airlift works as follows.

In the mixer 2 through the duct 4 enters the compressed air. On the suction inlet 5 into the mixer 2 enters the liquid or pulp. Compressed air, which possesses energy and moves at a certain speed, when interacting with a fluid, transfers part of its energy to the message of some part of the acceleration fluid, i.e. In the mixer 2 and at the entrance to the riser 1, an aero-hydraulic flow pattern is formed. Then, the air-hydraulic mixture moves upward through the lifting pipe 1 to the air separator 3. As it moves upward, the air entering the air-hydraulic mixture expands, increasing its volume and speed. When the air-mixture reaches the slots 8 in the riser 1, the excess air formed as a result of expansion enters the chamber 9 formed by the casing 6 and the riser pipe 1.

As a result, the airborne mixture, which is transported through the riser pipe 1 in the region of the slots 8, is freed from excess air. In this case, the relative speed of movement of the liquid and the remaining air is normalized, and therefore the rate at which the air slips relative to the liquid decreases. But at the same time, the aerohydrous mixture does not spend additional energy on the re-formation of the flow structure, since the aerohydrous mixture flow continues

up in the riser 1 of the same diameter, i.e. under unchanged conditions. The air leaving the riser 1 through the slits 8 enters the chamber 9 and is directed upwardly into the air separator 3. Further, in the air separator 3 from the chamber 9, air escapes through the annular nozzle 7, which, in addition to the lifting process, creates the effect of airborne mixture ejection. Since in chamber 9 through slots 8 of

the lifting pipe 1 enters not only air, but also liquid or slurry, then the cross section of chamber 9 provides the air velocity in its lower part of 2 m / s. At this speed of air, there will be no entrainment of particles of liquid or slurry up to the annular nozzle 7, only air moves in chamber 9, and the liquid returns back to riser 8 through slots 8.

Using the proposed airlift

increases efficiency by reducing energy losses in the aero fluid mixture.

Claims (1)

Airlift Invention Formulation, containing riser with slotted holes, in the lower part of which a mixer with an air duct and a suction pipe is installed, and in the upper part an air separator and a casing placed between the air separator and the pipe, communicating with the latter through the said holes located at its bottom, and made in the form of an open top glass, characterized in that, in order to increase efficiency by reducing hydraulic losses and using the ejection effect, the upper part of the glass is tapered to form an annular nozzle with a cut pipe, and inserted into the air separator.