SU64621A1 - Step lift with compressed air - Google Patents

Description

Stepped liquid lifters are already known, operating with compressed air, using a lifting tube consisting of individual segments connected by adjacent ends to a reservoir, adventurous to two air inlet and discharge lines m.

The present invention is directed to the further improvement of such liquid lifts and, in particular, to ensuring the continuity of fluid flow in all segments of the riser pipe. To this end, according to the invention, the reservoir of any stage of the lift is divided by a vertical wall into two chambers, which serve to receive and transfer fluid from the underlying segment of the riser pipe to the overlying section by alternating with the specified segments through the holes blocked by valves.

The drawing shows a diagram of a fluid elevator constituting the subject matter of the invention.

The following describes, as an example of one of the forms of fulfillment of isoorestation, a pneumatic stepped water lifter, designed to pump water from flooded mines or even to raise water from deep wells.

A pneumatic water elevator consists of a lifting pipe and a number of working tanks located along the depth of the pumped-out shaft.

Three pipes are connected to the working tanks along the pumped-out shaft outlet. Two side pipes a and a are air pipes, and one middle pipe is water-lifting.

Each working chamber is arranged as follows. Inside the tank, two chambers are formed using a vertical wall. The right (according to the drawing) camera with the top through the pipe is connected to the air pipe and IT at the bottom has two valves. The valve n opens in a pressure vessel located in the middle (I, from which the segment of the water-lifting pipe L originates, which goes to the overlying reservoir and adjoins its bottom. Other

the valve p is located in the bottom of the tank, opens into the chamber with and through its space communicates with a section of the water-lifting pipe b adjacent to the bottom of the tank.

The left chamber c is arranged similarly, i.e. at the top it is connected to the air pipe a and at the bottom it has two valves: n, opening inside the pressure vessel d, and t located in the bottom of the tank next to the lifting pipe.

The lower working tank differs from the others in that its bottom does not mate with the water-raising pipe, but ends with a suction nozzle e, through which and through the corresponding valves of the chamber can communicate with the external medium, i.e. with pumped water.

The system described above, consisting of pipes and a number of working tanks, being suspended as usual on the ropes, is lowered into the water of the pumped-out shaft. The water pipe b, extending from the uppermost working reservoir, is brought to the surface, and its end is bent to direct the water to the corresponding drain. The air supply and exhaust pipes a and a are connected to the compressor unit through an appropriate compressed air switch located on the surface near the compressor. Using this switch, the compressed air from the compressor, more precisely from the air collector, can be directed: either to the tube a - then the air will flow into the suction side of the compressor, or into the tube a - and then the compressor will suck the air out of the tube a.

The operation of the pneumatic water lifter is as follows.

If, suppose, the compressed air from the compressor unit goes through the right air duct pipe a, then from here it enters the right-hand chambers from all the tanks through the corresponding pipes and in these latter creates a pressure approximately equal to the pressure created by the compressor. Under pressure of compressed air, the valves t are closed, and the valves n are opened, and the water from each right chamber of the underlying reservoir is displaced through the corresponding pressure vessel d and through the lifting pipe to the overlying tank and from the uppermost reservoir water spills onto the surface. At the same time, from the left chambers from all working tanks the compressed air located there is drawn through the left air pipe and into the compressor. As a result, the pressure in the chambers rapidly decreases and conditions are created under which the valves t open and the water is injected through the water-lifting pipe, as mentioned above, due to the pressure of compressed air in the right chambers, it enters the left chambers of the overlying tanks with the valves closed. In the left chamber of the lowermost reservoir, water is sucked directly outside.

By the time the air pressure in the air pipe and under the influence of the suction of the compressor decreases to approximately atmospheric, the left chambers of all working tanks will be filled with water, and from the right chambers all the water will be forced out by compressed air, i.e. will end At this time, on the surface in the compressed air switch, the spool moves and changes the direction of air flow in the pipelines. Namely, now the compressed air from the air collector will flow into the left air pipe and from the right air pipe and the compressed air will be sucked out by the compressor. As a result, the processes in the chambers will change, i.e., water will be displaced in the left chambers, and in the right chambers the water will