SU808707A1 - Vacuum air lift - Google Patents

Description

(54) VACUUM ERLIFT

one

The invention relates to systems for transporting fluid, in particular, to the design of air-lift installations, and can be used in designing systems for transporting slurries, slurries, slurries, etc.

A vacuum airlift is known, which contains a vacuum chamber located at the upper end of the ascent pipeline, connected to a water-air boiler, and an air separator, communicated with the suction port of the compressor 111 ..

The disadvantage of such an airlift is the complexity and large amount of immersion required, as well as the high consumption of compressed air.

Closest to the proposed vacuum airlift contains feed and lifting pipes, a mixer with a pneumatic line placed between them and an air separator attached to the upper part of the lifting pipe, connected to a vacuum pump and having a barometric pipe fitted with a hydraulic lock 2.

The disadvantage of the known vacuum airlift is not enough opportunities, the ability to

heavy slurries, liquids with suspended precipitates.

The purpose of the invention is to expand the functionality of a vacuum airlift.

The goal is achieved by the fact that the barometric tube has a knee, on the inner surface of which a perforation is made,

0 a VOSKHOD5PDIY leg of the knee is equipped with a drain pipe and has a restrictive hole.

FIG. 1 shows a vacuum airlift, longitudinal section; in fig. 2 5 barometric pipe with drain pipe.

Vacuum airlift contains flow 1 and lift 2 pipes, the size: between them 3 mixer

0 by a pneumatic line 4 and an air separator 5 mounted on the upper part of the lifting pipe 2, connected to a vacuum pump (not shown) by line 6 and having a barometric nipple 7 equipped with a hydraulic lock 8, the barometric nipple 7 having a knee 9, on the inner surface of which is perforated 10, and ascending

0 section 11 of the knee 9 is provided with a drain

pipe 12 and has a restrictive hole 13.

Vacuum airlift works as follows.

Under the influence of the vacuum in the air separator 5, created by the vacuum pump, the pulp moves through the feed pipe 1 to the mixer 3. At the same time, air flows through the feed pipe 1 into the mixer 3 under the action of atmospheric pressure. In the mixer 3, the pulp and air are mixed, and an air-mixed mixture is formed, which moves up along the lifting pipe 2. Aerohydrous mixture, coming out of the lifting pipe 2, enters the air separator 5, where the air is separated from the pulp. The separated air rises upward through the air separator 5 and is sucked out by a vacuum pump (not shown), and the slurry is discharged into the barometric nipple 7. The liquid through the perforations 10 on the inner surface of the knee 9 of the barometric nipple 7 fills the water seal 8 above the level of the restrictive orifice 13, and the slurry thanks to the bend 9, the barometric nozzle 7 moves along it and is directed along the discharge pipe 12 to its destination.

A restrictive orifice 13 in the barometric nozzle 7 serves to increase the throughput, to supply atmospheric pressure to the air separator 5 when the vacuum airlift stops working and to provide the level of fluid in the air trap 8 necessary for normal start of the airlift. Some level of fluid in the hydraulic lock 8 should always be, since at the moment of launching the vacuum airlift, liquid from the hydraulic lock 8 enters the work through the perforation 10 of the barometric tube 7 enters it and prevents air from entering the air separator 5.

During vacuum airlift operation, the fluid level in the hydraulic lock 8 rises due to the influx of fluid through the perforations 10 in the baromeric port 7. The raised liquid level closes the restrictive orifice 13 in the barometric port 7 and the drain pipe 12 starts to work as a siphon system.

At the time of the shutdown of the vacuum airlift, the drain pipe 12 sucks the pulp from the barometric nozzle 7 with the pump of liquid from the hydraulic lock 8 through the perforation 10 on the barometric nozzle 7. As the level decreases

fluid in the hydraulic lock 8 to the restrictive orifice 13, atmospheric air enters the barometric connection 7, increases the pressure in it to the atmospheric air and at the same time prevents fluid from flowing through the pressure measuring connection 7, and in the hydraulic sealing 8 there remains the level of liquid required for normal start of the vacuum airlift .

0 The application of the present invention will allow the use of a vacuum airlift, working with small depths of the supply pipe for lifting heavy slurries, and significantly

5 to reduce the cost of manufacturing equipment and its operation).

Claims (2)

1. USSR Author's Certificate No. 115049, cl. F 04 F 1/20, 1960. 2.Porolo L.V. Air-gas liquid lifts (airgas elevators), M., Nedra, 1969, p. 136-139.