UA31464U - Submerged pump for dewatering - Google Patents

Abstract

A submerged pump for dewatering relates to pump building, in particular to pumps and pump units that are specially intended for liquid lift from large depths, for instance for dewatering in mines of metal mining industry and in underground vessels where large displacements is required, mostly in emergency situations, where there are no restrictions by cross dimension of pump and where use of no submerged pumps is impossible because of large depth of water lift.

Description

Description of the invention

The useful model applies to pump construction, in particular to pumps and pumping units specially designed for lifting liquids from great depths, for example for dewatering in mines of the mining industry and in underground tanks where large supplies are required, especially in emergency situations, there is no limit on the transverse size of the pump and where the use of non-submersible pumps is not possible due to the considerable depth of the water table.

Well-known submersible pumps for water reduction in the mining industry, which have a drive, a 710 suction body, several sequentially arranged stages (impeller with a correction device) and a pressure nozzle, for example, electric pumps ZCV 14-120-540 ХТрГ, ZCV 14-210-300 ХГ and ZCV 16-375-175 KhG.

The sequentially arranged stages in them provide the necessary pressure with a given supply |11 by their number.

The disadvantage of well-known submersible pumps, which are produced in the CIS, is the limitation of their nominal supply of 375 mm

З/г. Moreover, this limitation is typical for similar pumps of leading Western European companies. For example, the pumps of type 5P of the company "Grundfoss" (Germany) are limited to a supply of 230m3/h |2), pumps of type 5-2528 of the company "ZAEV" (Italy) are limited to a supply of 375m З/h |З). At the same time, pumps with a flow rate of 800-1000m3/h at lower pressures are often needed for dewatering in mines of the mining industry, especially when eliminating an accident in them. This is explained by the small demand for them for water reduction in mines and the desire to unify them with well pumps, which are limited in transverse size by the diameter of the well, which limits their supply. And the creation and development of special submersible pumps with large transverse dimensions of their stages and supplies only for water reduction in the mines of the mining industry is expensive and economically unprofitable due to the low demand for them.

The basis of a useful model is the task of a submersible pump with several stages for

Water lowering, where there are no restrictions on its transverse dimensions, by dividing its stages into equal parts and connecting them with a pressure nozzle in parallel through a special intermediate body, make it more o) productive without creating for this purpose new stages with a larger transverse dimension and supply, i.e. at preservation of unification by stage (by an impeller with a correction device) with a well pump and without the costs of creating and mastering the production of new stages. hE

This goal is achieved by the fact that in a submersible pump for water reduction, which has a drive, a suction body, several successively located stages (impeller with a correction device) and a pressure nozzle, the stages are divided into equal parts by an intermediate body, in which two types of "g" are provided flow channels, through one of which and through external side pipes connecting this type of channels with a pressure nozzle, the water that is pumped out by the lower part of the steps is fed into this nozzle, and through "--

Зз5 the second - water that is pumped out is sucked into the upper part of the steps, by which it is also fed into the pressure pipe, where the water flows are added to the general supply of the pump, which increases in proportion to the number of equal parts of the steps. To reduce the resistance to water movement in the intermediate body, the channels that connect to the side pipes and are made in the ribs connecting its flanges are made compressed with a transition at the exit to the shape of the inner surface of the outer side pipes. To ensure the maximum unification of pumps with different " 70 Number of equal parts of the stages, their external side pipes are made removable with a connection with an intermediate hose with a housing and a pressure nozzle. To compensate for manufacturing deviations in the length of the pressure nozzle, and the intermediate housing and external side pipes, these pipes are connected to the intermediate housing in an unfixed axial "" direction.

This set of known essential features, which consists in the presence of a submersible pump for dewatering the drive, a suction body, several successively located stages and a pressure nozzle, in interaction with new essential features, consisting in the division of its stages into equal parts, which are connected in parallel through intermediate housing and external side pipes with a pump pressure nozzle, in the design of flow channels made in the ribs of the intermediate housing, compressed with a transition to the shape of the inner surface of the external side pipes, and in the design of these pipes removable with a non-fixed connection in the axial direction with an intermediate casing, allows, due to a minor modification of the well-known well pump, while (22) maintaining the uniformity with it in terms of stages and without the costs of creating and developing new stages in the production of a submersible pump with the necessary supply for water lowering, which can be several times higher than the existing at well pumps, which forces but are used for this.

Fig. 1 shows the proposed submersible two-stage (to simplify the figure) pump for water reduction in an axial section on the right and in a side view on the left, in Fig. 2 - a cross section A-A along the axis of the channel of the outer pipe and the upper part of the flow channel of the intermediate body, in Fig. .3 - variant of non-fixed connection from the external side pipe to the intermediate housing.

The pump has a drive (submersible electric motor) 1, the pump itself 2, which are connected to each other through the suction body 3. The pump itself 2 consists of the lower 4 and the upper 5 identical stages (the working wheel with the correcting device), which are connected between itself through the intermediate housing 6, the pressure nozzle 7, which is connected to the upper stage 5 and through the external side pipes 8 - to the intermediate housing 6. The connection of the external side pipes 8 to the intermediate housing is made non-fixed in the axial direction using a flange 9 with a sealing ring 10 or only through a sealing ring 10 (var. I) to compensate for manufacturing deviations along the length of the parts included in this connection. 65 The flow channels 11 of the intermediate housing 6, which are made in its ribs and connect the lower stage 4 with the pressure nozzle 7 through the outer side pipes 8, are made compressed to reduce the resistance of water absorption into the upper stage with a transition in the upper part to the shape of the inner surface of the outer side pipes 8. To prevent water from flowing from the pressure cavity of the intermediate housing 6 into its suction cavity through the gap between it and the pump shaft, a seal 12 is provided in this place.

The pump works like this.

To install the pump in the mine, it is connected with a pressure pipe 7 to the water-lifting pipeline (on

Fig. not shown), on it the pump is lowered into the mine, immersing it in the water to be pumped out, and suspended. They include the electric motor 1, which rotates the working wheels of stages 4 and 5. During their rotation, the water sucked by the lower stage 4 is fed by it through the flow channels 11 of the intermediate body 6 and through the external side pipes 8 into the pressure nozzle 7, and the water sucked by the upper stage 5, is fed by it directly into the pressure nozzle 7. Thus, these two stages work in parallel mode, and the supplies created by them in the pressure nozzle 7 are added to the total pump supply, which is proportional to the number of stages or their parts, which are separated by an intermediate housing 6. In this case, for example, it is doubled. The directions of water flow during pump operation in Fig. 1 are indicated by arrows. The necessary pressure of the pump is provided by the number of stages in each of their equal parts, which are divided into intermediate housing 6. With a change in the number of stages and their parts, only the length of the external side pipes 8 changes, all other parts remain unified among themselves and between the parts of the well pump (except for the shaft ), on the basis of which this proposed pump is created. This allows you to create and manufacture a submersible pump for water reduction in a short time and without significant costs, having purchased a drive of the appropriate power for it, which is especially important in case of emergency flooding of mines.

Sources of information: 1. Submersible water pumps. Catalogue. The second payment, corrected and supplemented.

TSYNTIKHYMNEFTEMash. Moscow. 1989. p.4 (issue 3), 17, 18. 2. OKOMORO5. Well pumps ЗР, МР1И, 5РА-МЕ, ЗР-МЕ. p. 69. 3. General catalog. ZAEK EI EKTKOROMRE. 2007. p. 226 Z

Claims (4)

The formula of the invention is 1. A submersible pump for water reduction, which has a drive, a suction body, several sequentially arranged stages (an impeller with a correcting device) and a pressure nozzle, which is distinguished by the fact that its stages are divided into equal parts by an intermediate body, in which is provided with two types of flow channels, made in such a way that through one of them and through the external side pipes connecting this type of channels with the pressure nozzle, the water that is pumped out by the lower part of the steps is fed into this nozzle, and through the second - water that is pumped out was sucked into the upper part of the steps, by which it is also fed directly into the pressure nozzle, where the water flows are added to the total supply of the pump, which increases in proportion to the number of equal parts of the steps. 2. The pump according to claim 1, which differs in that the channels of the intermediate body, which connect to the side pipes and are made in the ribs connecting its flanges, are made compressed with a transition at the exit to the shape of the inner surface of the outer side pipes. Z7Z 3. The pump according to claim 1, which is characterized by the fact that its external side pipes are made removable with connections with an intermediate body and a pressure nozzle. :with" 4. The pump according to claim 1, which is characterized by the fact that the outer side pipes are connected to the intermediate body in an axially fixed manner. z - FT" (22) ch s 60 b5