MD724Z - Glandless vane motor pump - Google Patents

Abstract

The invention relates to the hydraulic mechanical engineering, namely to glandless motor pumps for pumping liquids.The glandless vane motor pump comprises a pump section (1) with an impeller (2) with blades and a sealed electric motor (6), between which is placed a heat-insulating partition wall (4) with a face seal (5). The electric motor (6) is provided with an autonomous cooling system, consisting of a cooling jacket (9) with cooling liquid inlet and outlet pipelines, mounted on the housing of the electric motor (6). In the cooling jacket (9) is placed a coil (10), each end of which is connected to an outer tube (11), in which is made a hole, each closed with a plug (13). One of the tubes (11) is connected to a channel, made in the bearing shield (15) on the opposite side of the pump section (1), communicating with the chamber of an auxiliary wheel (17) for recirculation of the cooling liquid, fixed on the shaft of the electric motor (6). The other tube (11) is connected to a channel, made in the bearing shield (15) on the side of the pump section (1), communicating with a channel, made in the partition wall (4). The chamber of the auxiliary wheel (17) and the channel of the partition wall (4) communicate with the cavity of the electric motor (6).

Description

The invention relates to the construction of hydraulic machines, namely to hermetic electric pumps for pumping liquids.

A hermetic electric pump with blades of the BЭН type is known, which contains a pumping part, a thermally insulating partition, a hermetic electric motor and a cooling system for it with a circuit filled with coolant circulated by an auxiliary wheel, the circuit being equipped with a coil, which communicates with both sides of the electric motor cavity and with a cooling jacket, in which the electric motor is incorporated [1].

The disadvantages of this pump are that through the clearance between the shaft and the partition wall, the cavity of the electric motor hermetically communicates with the chamber of the pumping part, therefore the cavity and the circuit of the cooling system of the electric motor are made non-autonomous. Before the first start of the electric pump, it is filled with pre-cooled pumping liquid, which during the operation of the pump, thanks to the auxiliary wheel, circulates through it, cooling the outer surface of the rotor and the inner surface of the stator of the electric motor, at the same time through the clearance between the shaft and the partition wall the cooling liquid mixes with the pumping liquid and is heated by it. Since the pumped liquid has a high temperature (for example, 200…250°C) and solid inclusions are allowed in it (for example, with dimensions up to 0.2 mm and mass fraction up to 0.2%), they increase the viscosity of the liquid upon cooling, after the pump is switched off, this reduces the efficiency of cooling the electric motor, accelerates the wear of the internal surfaces of the stator and external surfaces of the rotor of the electric motor, plain bearings and other parts that come into contact with solid inclusions. Increasing the viscosity of the liquid, which cools after the pump is switched off, and the deposition of solid inclusions in the clearances between the rotor, stator and plain bearings, when the pump is switched off, can lead to overloading of the electric motor at subsequent pump starts. This reduces the reliability of the hermetic vane electric pump.

The technical problem solved by the invention consists in creating a hermetic electric pump with blades by separating the pumping part and the electric motor cavity, implementing an autonomous cooling system (which does not communicate with the pumping part), as well as increasing the reliability of the electric drive motor and the pump as a whole.

The hermetic electric vane pump, according to the invention, eliminates the above-mentioned disadvantages by containing a pumping part with a vane impeller and a hermetic electric motor, between which a heat-insulating partition with a front seal is placed. The electric motor is equipped with an autonomous cooling system, consisting of a cooling jacket with inlet and outlet pipes for the coolant, mounted on the body of the electric motor. A coil is placed in the cooling jacket, each end of which is connected to an outer tube, in which a hole closed with a plug is made. One of the tubes is connected to a channel, made in the bearing shield of the electric motor, fixed to its body on the side opposite the pumping part, which communicates with the chamber of an auxiliary wheel for recirculating the coolant, fixed on the shaft of the electric motor. The other tube is connected to a channel, made in the bearing shield of the electric motor, fixed to its body from the pumping side, which communicates with a channel, made in the partition wall. The auxiliary wheel chamber and the partition wall channel communicate with the electric motor cavity.

The autonomous cooling system may contain a compensator, equipped with a device for visual observation of the liquid level, and a resistance thermometer.

The set of essential elements of the hermetic electric vane pump increases its reliability, which allows the consumer to reduce repair costs and purchases of new pumps.

Equipping the autonomous cooling system with a compensator ensures the possibility of increasing the thermal volume of the liquid in the cooling system and reduces the pressure increase in it, which can lead to the destruction of the electric motor and the cooling system. To monitor the level of the pumped liquid in the cooling system circuit, the compressor can be equipped with a visual observation device.

The invention is explained by the drawing in the figure, in which the hermetic electric pump with blades is represented.

The electric pump contains the pumping part 1 with the impeller 2 with blades and the helical connection 3, the heat-insulating partition 4 with front seal 5, which separates the pumping part 1 from the hermetic electric motor 6 with the stator 7 and the rotor 8. The electric motor 6 is equipped with the autonomous cooling system, consisting of the cooling jacket 9 with inlet and outlet pipes of the coolant, mounted on the body of the electric motor 6. In the cooling jacket 9 is located the coil 10 of the circuit of the autonomous cooling system of the electric motor 6, each end of which is connected to an external tube, in which a hole closed with a plug is made. One of the tubes is connected to a channel, made in the bearing shield of the electric motor, fixed to its body on the side opposite the pumping part, which communicates with the chamber of an auxiliary wheel for recirculating the coolant, fixed on the shaft of the electric motor. The other tube is connected to a channel, made in the bearing shield of the electric motor, fixed to its body from the pumping side, which communicates with a channel, made in the partition. The auxiliary wheel chamber and the partition channel communicate with the electric motor cavity. The circuit of the autonomous cooling system is filled with circulating liquid through one of the holes on the outer tubes 11, while the second hole is open, or through the compensator 12, while both holes are open. The holes on the outer tubes 11, after filling the cooling system with circulating liquid, are closed with plugs 13. The rotor 8 is placed in the electric motor 6 on radial sliding bearings 14, on both sides of the electric motor 6. In the cooling jacket 9, two cold water inlet and outlet holes are made for washing it, closed with plugs 18. The circuit of the autonomous cooling system can be equipped with a resistance thermometer 19 and a device for visual observation 20 of the liquid level.

The hermetic electric vane pump operates in the following way.

Before starting the pump, remove the plugs 13 and through one of the holes, or through the compensator 12, fill the circuit of the autonomous cooling system of the electric motor 6 with circulating coolant, at the same time follow the second open hole, through which air comes out, until the liquid appears. During these operations, when the electric pump is stopped and running, the front seal 5 separates the pumping part 1 from the electric motor 6. After closing the plugs 13 and, if necessary, adding coolant through the compensator 12 until it is possible to control the liquid level through the visual observation device 20, the cooling jacket 9 is connected to the cold water pipe by means of flanges. The electric pump is started. During its operation, the auxiliary wheel 17 rotates together with the rotor 8, forcing the coolant in the circuit of the autonomous cooling system to circulate through the gap between the rotor 8 and the stator 7, cooling them, through the channels of the bearing shields 15 and through the coil 10, in which the liquid is cooled by cold water, which passes through the cooling jacket 9, in which the coil 10 is incorporated. The direction of movement of the coolant circulating in the circuit of the autonomous cooling system is indicated by arrows in the figure. Monitoring the temperature of the coolant circulating and, if necessary, its level in the circuit of the autonomous cooling system, can be carried out appropriately with the resistance thermometer 19 and the visual observation device 20 of the liquid level.

The proposed technical solution, due to the circuit of the autonomous cooling system of the electric motor, allows filling it with liquid, without solid inclusions, with minimal viscosity and with a temperature much lower than the pumped liquid. This increases the reliability of the electric pump, reduces the wear of the friction surfaces of the electric pump parts and the loads on the electric motor, especially its heating during the start-up of the electric pump and during its operation.

1. Насос БЭН-213/1, 2002, <url: http:http://nasos.info/catalog.php?mode=view&id=2916> (retrieved on the Internet on 2013.10.09)

Claims (2)

1. Hermetic electric pump with blades, comprising a pumping part (1) with an impeller (2) with blades and a hermetic electric motor (6), between which is placed a thermally insulating partition wall (4) with a front seal (5); the electric motor (6) is equipped with an autonomous cooling system, consisting of a cooling jacket (9) with inlet and outlet pipes for the coolant, mounted on the body of the electric motor (6), in the cooling jacket (9) a coil (10) is placed, each end of which is connected to an outer tube (11), in which a hole is made, each closed with a plug (13); one of the tubes (11) is connected to a channel, made in the bearing shield (15) of the electric motor (6), fixed to its body on the side opposite the pumping part (1), which communicates with the chamber of an auxiliary wheel (17) for recirculating the cooling liquid, fixed to the shaft of the electric motor (6); the other tube (11) is connected to a channel, made in the bearing shield (15) of the electric motor (6), fixed to its body on the side of the pumping part (1), which communicates with a channel, made in the partition wall (4), at the same time the chamber of the auxiliary wheel (17) and the channel of the partition wall (4) communicate with the cavity of the electric motor (6). 2. Pump according to claim 1, wherein the autonomous cooling system comprises a compensator (12), equipped with a visual observation device (20) of the liquid level, and a resistance thermometer (19).