JPS61118595A - Cooling device for submersible pump - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a cooling device for a motor that electrically drives a submersible pump.

[Conventional technology]

Pumping systems used in offshore installations on ships, for example used to transport oil or chemical products, have a pump body that has an impeller and a motor chamber that contains an electric motor that drives the impeller. ing. The pump body is supported at the lower end of a vertical tube suspended from a support plate, and the vertical tube is provided with a discharge duct for discharging discharged water and a conductive cable for supplying energy to an electric motor.

The electric motor in the pump body necessarily generates considerable waste heat and must be cooled if a long operating life is to be expected. Conventional cooling is performed by cooling the casing containing the motor.
Methods have been used to provide a flow of water pumped from the outside or to circulate an insulating liquid through the casing (see European Publication No. 63444/2013).

[Problem that the invention seeks to solve]

The present invention includes a pump body immersed in water for pumping water, an impeller for pumping water, an electric motor for driving the impeller, and a device for producing a flow of cooling water in the motor casing to cool the motor. The present invention provides a cooling device for a submersible pump.

[Means for solving problems]

It is possible to exchange heat with the motor by actually introducing pumped water into the inside of the motor casing, and a greater cooling effect can be obtained than that obtained by supplying cooling water from the outside of the casing. be able to.

Preferably, the pumped water flows in a helical cooling pipe extending between the motor and the casing and surrounding the motor. Part of the pumped water introduced through the motor casing and the combined water pumped by the impeller
It is only a small part of @.

After cooling water flows through the channel in the sink, it is discharged to the outside of the pump body.

According to the invention, an auxiliary impeller is used, but the cooling water is forced through the motor casing under the pressure generated by the pump impeller. By throttling the discharge valve to reduce the water flow at the discharge station, the flow of cooling water tends to increase with a restriction of pump output. Although such a decrease in the output flow rate increases heat generation within the pump, the cold water device according to the present invention uses a part of the output flow ω as cooling water. In some cases, operation can be continued with the discharge valve fully open (with the discharge valve fully open), and operation is possible without overheating. The pumped water that flows through the casing is drawn from the leakage water that has passed through the worn casing, which is mounted between the rotating impeller and the contact surface of the casing, the claw of which is 3 to 5% of the confluence m. The interior of the casing can be filled with an insulating liquid, which can be circulated through circuits in the casing for cooling, and the pumped water can be sent by a stand to a discharge station. As shown in European publication 634471, a pump and heat exchanger are installed at the discharge station. However, according to the present invention, cooling can be achieved by circulating an insulating liquid within the casing.

(Example) Hereinafter, an example of a cooling device for a submersible pump according to the present invention will be described with reference to the drawings.

In the drawings, FIG. 1 shows a pump device, which has a stand 11 suspended from a support plate 2, a pump body 4 is provided at the lower end of this stand tube 1, and the stand tube 1 is It is submerged in water pumped by the impeller of the pump, and the pumped water is discharged through a discharge valve (not shown) on the support plate 2. The chamber cylinder 1 consists of an inner tube 5 and an outer tube 6 that are arranged concentrically, and a support plate 2 is provided inside the inner tube 5.
An electrically conductive cable is routed from the pump body to an impeller disposed within the pump body for driving the impeller. The annular space between the inner tube 5 and the outer tube 6 serves as a discharge duct through which water is pumped upward to the drainage stage.

The pump body 4 as shown in FIGS. 2A 45 and 2B comprises an inner casing 10 having a cylindrical side wall 11 and an upper fitting end 12, the inner casing 10 being connected to the inner pipe 5 by the upper fitting end 12. be done. Said inner casing 10 is arranged inside an outer casing 20 having a similar cylindrical side wall 21 . The side wall 21 and the side wall 11 are concentric, and a mounting 7 flange 22 is connected to the outer tube 6. The annular space between the inner casing 10 and the outer casing 20 communicates with the discharge passage of the upright Ill, and the water to be pumped passes therethrough. An electric motor is disposed inside the inner casing 10,
This electric motor has a drive shaft 14 supporting a rotor 15 surrounded by an annular stator 16.

The inner casing 10 has a support member 17 at its lower end, which is provided with an inwardly directed portion 17b connected by an upper annular lug 17a. The upper end of the drive shaft 14 of the motor is supported by the lower end of the inner cylindrical part 17b, while the outer surface of the outer cylindrical part 17c of the support member 17 is supported by the stator 16.
An annular chamber 24 is formed between the side wall 11 and the outer peripheral surface of the side wall 11 . ;1. - (The conductive cable wired inside the inner tube 5 of the cylinder 1 is connected to the stage 16 by a connecting force IA 25, and the connecting conductor 25 is installed in the frontage of the upper annular tube 17a of the support member 17. The insulation pusher 126 extends through the insulation pusher 126.

The lower support member 27 has a concentric inner sleeve 27a and an outer sleeve 27b connected in five to the annular web at the lower end and seats on two inwardly extending flanges of the side wall 11; and sealed. Inner sleeve 27 a +J of lower support member 27, drive! 1iJ
The outer races of two ball bearings 30 spaced apart from each other in the Tlk direction are housed and held therein. Also, the outer sleeve.

An annular chamber 24 is formed outside 27b.

, L. 14 extends downward through two flanges and is fitted with an impeller 31.31 for pumping water.

The mounting end 12 of said inner gauging 10 is connected to the inner tube 5, and the inner casing 10 has an insulating or Filled with insulating liquid. The above-mentioned insulating liquid is supplied to the inner pipe 5 from a header tank 7 located on the support plate 2, and the liquid level in the tank is maintained under sufficient static pressure to prevent leakage of water pumped into the casing. Retains liquid. Circulation of the insulating liquid within the casing 10 is performed by an auxiliary impeller 35 mounted on the drive 1llll@14 directly below the ball bearing 30. The insulating liquid flows from the annular chamber 24 into the lower support member 27 111! II or through two or more radial passages 36 by the impeller. The sucked insulating liquid is discharged into the ball bearing 30 and into the space between the inner sleeve 27.8 and the outer sleeve 27b of the lower support member 27. When the insulating liquid is discharged upward through the gap between the stator 15 and the stator 16, the insulating liquid flows into the web 17 of the support member 17.
It reaches the inside of the mounting end through the passage in a. Then, the circulating insulating liquid passes through the plurality of passages formed on the outer edge of the r-cube 17a of the support member 17 and returns to the annular chamber 24.
Go inside. A seal holder 37 is attached to the lower support member 27 below the auxiliary impeller 35, and the auxiliary impeller 37 is attached between the seal holder 37 and the drive@14.
A circular artificial space for 5 is formed. The seal holder 37 holds a sealing element 39 that engages with the drive shaft 14 to seal the lower end of the inner casing 10. Above side W! Two wear rings 40 and 41 are attached to the lower surface of the two 7 langes formed at the lower end of the flange 11, and a wear ring 42 that protrudes downward is protruded between them, and the tip thereof is connected to the impeller. While he was on the back of 31, that W! The end is remote from the flange 29.

The discharged water leaking inward through the engaging portions of the wear rings 40, 41, 42 flows into the annular chamber 44 whose upper surface is closed by the seal holder 37. The annular chamber 44 communicates with the outside of the C pump through a radial passage 45 in the seven flange 29 and is at the same pressure as the surrounding water. Since the seal for the drive shaft 14 in the seal holder 37 is located between the annular chamber 44 and the suction port of the auxiliary impeller 35, the seal is simple and an inexpensive sealing element 39 can be used.

The heat generated by the electric motor is transferred to the casing 10 by conduction, and some of the heat can be removed by transferring the heat to the water flowing out of the casing.

However, by adding some means to the pump body, the pumped water can remove heat from the motor.

The seven flange 29 has a passage 50 which opens into the space between the fixed rings 40 and 41 above the wear ring 42 of the impeller. This passage 50 communicates with a cooling pipe 51 at its upper end, and the cooling pipe 51 is connected to one stator 16,
Piping is arranged helically within an annular chamber 24 formed between the support member 17 and the lower support member 27 and the other inner side wall 11 . The upper end of the cooling pipe 51 communicates with an outlet pipe 52 passing through the upper end of the inner side wall 11, and the outlet pipe 52 crosses the space between the inner casing 10 and the outer casing 20, and the outlet pipe 52 crosses the space between the inner casing 10 and the outer casing 20, It passes through and opens to the outside of the pump body. 3-5% of the water pumped by the impeller 31 leaks inward through the rings 40, /11 and 42, the equivalent of which flows through the passage 50, the cold 7. (l
It flows out through tube 51 and outlet tube 52. A cold Nj pipe 51 surrounding the motor exchanges heat with the stator 16 in cooperation with the insulating liquid in the annular tube 2'. The amount of heat removed from the motor is significantly increased compared to heat removal only through the inner sidewall 1. In this way, the operating life of the pump body is extended. This is because the flow rate through the cooling pipe 51 increases as a result of the increase in pressure within the discharge duct.

[Brief explanation of the drawing]

Fig. 1 is a side view schematically showing a bomb system incorporating a submersible pump according to the present invention, and Fig. 2A is an enlarged vertical cross-sectional view of the upper half of the pump body shown in Fig. 1. , second
Figure B is an enlarged longitudinal sectional view of the lower half of the pump body. DESCRIPTION OF SYMBOLS 1... Vertical tube, 2... Support plate, 4... Pump main body, 10... Inner casing, 11... Side wall, 14...
... Drive shaft, 15 ... Rotor, 16 ... Stator,
17... Support member, 20... Outer casing, 21
... side wall, 27 ... lower support member, 29 ... flange, 31 ... blade inside, 35 ... auxiliary impeller, 40
．． 41.42...wear ring.

Claims (1)

[Claims] 1. An electric casing that includes an impeller that pressurizes water, an electric motor that drives the impeller, and a device that generates a flow of cooling water into the electric casing to cool the electric motor. A cooling system for submersible pumps. 2. The cooling device for a submersible pump according to claim 1, wherein the water flowing inside the electric casing is driven by an impeller. 3. Claim 2, wherein the impeller is located below the motor, and the cooling water flow path extends upward within the electric casing and extends to the outside of the pump body. A cooling device for a submersible pump described in . 4. Claims 1 to 3, characterized in that a sealing device is provided between the impeller and the casing, and the cooling water is drawn out through this sealing device.
The cooling device according to any of paragraphs. 5. The sealing device has a first pair of engaging sealing surfaces and a second pair of engaging sealing surfaces between the impellers, and the cooling water flow is directed between the first and second inlets. A leakage flow path to the outside of the pump includes a flow path located between the sealing surfaces of the pump and having an outlet opening to the outside, and a leakage flow path to the outside of the pump includes an outlet located inside the sealing surface. Range 3rd or 4th item
The cooling device described in Section. 6. The sealing device has inner and outer wear rings provided on one of the casing and the impeller, and an intermediate wear ring provided on the other, and the cooling water flow path is 6. Cooling device according to claim 5, characterized in that the inlet comprises a flow passage located above the intermediate wear ring. 7. The cooling device according to claim 6, characterized in that the inner chamber of the wear ring communicates with the outside of the pump. 8. The electric motor is arranged to drive an auxiliary impeller in the casing, the auxiliary impeller circulates an insulating liquid, and the auxiliary impeller is connected to the impeller chamber by a sealing element between the casing and the motor. 8. Cooling device according to claim 7, characterized in that it comprises an inlet separate from the inlet. 9. The electric motor has an annular stator portion extending outside the casing 7 and positioned around the rotor driving the impeller, so that the flow of cooling water is guided between the stator and the casing. A cooling device according to any one of claims 1 to 8, characterized in that: 10. The cooling device according to any one of claims 1 to 9, characterized in that the flow of cooling water is guided in a helical flow path around the electric motor within the casing.