RU68618U1 - Airlift - Google Patents

Abstract

The utility model relates to systems for transporting liquid, in particular, to the design of airlift systems and can be used in the design of systems for the transport of suspensions, suspensions, pulps, etc. An airlift containing a compressor, supply and lift pipes, an air trap with a water seal, mounted on the top of the lift pipe and connected to the compressor, additionally contains a single valve system that allows the compressor to operate in both vacuum and compressor mode, and the supply pipe is connected to a lifting pipe with several mixers to increase the lifting force and accelerate the lifting of the air mixture. 1 ill.

Description

The utility model relates to systems for transporting liquid, in particular, to the design of airlift systems and can be used in the design of systems for the transport of suspensions, suspensions, pulps, etc.

Known vacuum airlift [ed. St. No. 808707 of 02/28/1981], containing a supply and a lifting pipe, a mixer with a pneumatic conduit placed between them, an air separator fixed to the top of the lifting pipe, connected to a vacuum pump and having a barometric nozzle equipped with a water seal, the barometric nozzle has an elbow on the inner surface which is perforated, and the ascending section of the knee is equipped with a drain pipe and has a restrictive hole.

The disadvantage of this airlift is insufficient productivity, high start-up pressure and relatively low vacuum.

The objective of the utility model is to increase productivity, reduce energy consumption when starting airlift in vacuum mode.

The task is achieved in that the airlift contains a vacuum compressor, supply and lift pipes, an air trap with a water seal, mounted on the top of the lift pipe and connected to a vacuum compressor, a single valve system that allows the vacuum compressor to work in both vacuum and in the compressor mode, the feed pipe is connected to the lift pipe by several mixers to accelerate the ascent of the mixture consisting of water with sand and air (aero-fluid mixtures).

The proposed airlift is conditionally presented in figure 1

Airlift contains a vacuum compressor 1, a supply pipe 2 for supplying air and a lift pipe 3, mixers 4 and 5, an air separator 6, mounted on the top of the lift pipe, connected to a vacuum compressor 1, a single valve system (valve 7, shut-off valve 8 , outlet valve 9, valve for adjusting the air supply 10), a water trap 11 of the air separator 6, a drain pipe 12.

Airlift works as follows.

Compressed air from the vacuum compressor 1 (shut-off valve 8 is closed) through the valve 10, for regulating the air supply, enters the mixers 4 and 5 through the supply pipe 2, while water and sand (pulp) enters the mixers 4 and 5 under the pressure of a liquid column . In mixers 4 and 5, pulp and air are mixed to form an air-gas mixture. The air-gas mixture moves up in the lifting pipe 3 due to a decrease in its density and enters the air separator 6, where air is separated from the pulp. The separated air rises and through the valve 7 goes into the atmosphere, the pulp through the water trap 11 of the air separator 6 enters the drain pipe 12 to separate the sand from the water.

In start-up mode, valve 7 is closed, and valve 8 is open. Moreover, during start-up, the vacuum compressor 1 operates in a vacuum mode (and thereby ensures a decrease in vacuum in the airlift system, for it to enter the operating mode). Under the influence of rarefaction in the air separator 6, created in a vacuum mode, the pulp moves in the riser 3. The suction air is discharged into the atmosphere through the outlet valve 9. The air trap 11 of the air separator 6 serves to create a vacuum in the airlift system.

In operating mode, the vacuum compressor 1 operates as a compressor. Shut-off valve 8 is closed, valve 7 is open. Outlet valve 9

serves for suction of air by a vacuum compressor 1. Valve 10 serves to control the air supply to the mixers 4 and 5.

The mixer 5 serves to increase the lifting force and accelerate the lifting of the air-fluid mixture (consisting of water with sand and air) in the lifting pipe 3 and thereby increases the performance of the airlift. The increase in lift depends on the distance between the mixers l, the compressor operation (pressure, productivity) and the depth of the dynamic water level in the well.

Thus, the proposed airlift allows you to increase the performance of the entire installation and reduce energy consumption when starting airlift in a vacuum mode.

Claims (1)

An airlift containing a compressor, supply and lift pipes, an air trap with a water seal, mounted on the top of the lift pipe and connected to the compressor, characterized in that it further comprises a single valve system, which allows the compressor to operate both in vacuum and in compressor mode, and the feed pipe is connected to the lifting pipe by several mixers to increase the lifting force and accelerate the lifting of the air mixture.