KR102432443B1 - Pump with leak-proof structure of bearing lubricant - Google Patents

Abstract

The present invention relates to a pump with a leak-proof structure of a bearing lubricant. The present invention aims to provide a pump with a structure which prevents a lubricant in a bearing chamber from leaking. To this end, according to the present invention, in the pump, an impeller is placed to rotate and absorb and discharge a fluid, and is connected to a rotary shaft extended from a motor, so that the impeller rotates along with the rotary shaft and pumps the fluid. One or more of bearings supporting the rotary shaft are accommodated in the bearing chamber formed in the pump main body. The inside of the bearing chamber is filled with the lubricant. An oil seal is installed in the bearing chamber for preventing the lubricant from leaking. An auxiliary impeller is additionally installed in the bearing chamber for flowing the lubricant to the opposite direction to the oil seal while rotating along with the rotary shaft. Between the auxiliary impeller and the oil seal, a negative pressure space is formed to reduce pressure while the lubricant is taken out by the auxiliary impeller when the auxiliary impeller rotates. Between an outer circumference of the bearing and a bearing housing, a circulation passage is formed so that the lubricant flowing by the auxiliary impeller can pass through.

Description

Pump with leak-proof structure of bearing lubricant

The present invention relates to a pump, and more particularly, the auxiliary impeller for flowing the lubricant filled in the bearing chamber inside the pump is further installed inside the bearing chamber, wherein the auxiliary impeller is a lubricant in the opposite direction to the expected leakage point It relates to a pump having a leakage preventing structure of a bearing lubricant configured to prevent leakage of lubricant while flowing.

In general, a pump is used to transport a fluid, and a pump that sucks and discharges the fluid using an impeller rotating at a high speed is mainly used.

In the case of a pump that transports fluid through the rotation of the impeller as described above, the impeller is disposed in the pumping chamber connected to the suction port and the discharge port, and the rotating shaft extending from the motor to the inside of the pumping chamber is connected to the impeller so that the impeller is operated by the operation of the motor. It is configured to pump the fluid while rotating.

On the other hand, the rotating shaft connecting the motor and the impeller is coupled to the pump body through a bearing to stably support the impeller while rotating at high speed together with the impeller, and the bearing supporting the rotating shaft is inside the bearing chamber filled with lubricant. is installed on

FIG. 1 is an internal structural diagram of a conventional submersible sand flow pump, and FIG. 2 is a detailed view of part 'A'.

In the submersible sand flow pump shown in FIG. 1 , the impeller 20 is disposed in the pumping chamber 11 provided at the lower end of the pump body 10 , and the rotor 31 and the stator 32 are disposed at the upper end of the pump body 10 . A motor 30 made of is formed, and a rotation shaft 40 of a vertical posture is installed to connect the rotor 31 and the impeller 20 .

Bearings B1, B2, and B3 are installed at the upper end and lower end of the rotary shaft 40, and some or all of these bearings B1, B2, B3 are formed in the pump body 10 of the bearing chamber 12 of It is disposed therein, and the inside of the bearing chamber 12 is filled with a lubricant.

On the other hand, when the pump operates, heat is generated in the bearing B1 due to the rotating shaft 40 rotating at high speed, and the temperature of the lubricant increases due to the heat generated in the bearing B1, the viscosity decreases, and the low viscosity lubricant may be more easily discharged to the outside of the bearing chamber 12 through the oil seal 13 .

On the other hand, when the lubricant in the bearing chamber is leaked, the frictional resistance of the bearing increases, so more energy is consumed during pump operation, and noise and vibration are generated. In severe cases, the bearing is damaged and loses its function. There is a problem.

In addition, there is a problem in that the lubricant leaked from the bearing chamber is scattered around by centrifugal force to cause contamination inside the pump.

Registered Utility Model Publication No. 20-0293631 (2002.11.01. Announcement)

The present invention has been made in consideration of the above problems, and an object of the present invention is to provide a pump including a structure for preventing leakage of a lubricant filled in a bearing chamber.

Another object of the present invention is to provide a pump that allows a lubricant filled in a bearing chamber to flow more smoothly.

Another object of the present invention is to provide a pump that prevents the lubricant from sticking by allowing the lubricant in the bearing chamber to continuously flow during operation of the pump.

The present invention, which achieves the object as described above and performs the task for eliminating the conventional drawbacks, has an impeller for sucking and discharging fluid while rotating is disposed therein, and the impeller is connected to a rotating shaft extending from the motor and connected to the rotating shaft and A pump configured to pump a fluid while rotating together, wherein at least one of the bearings supporting the rotating shaft is accommodated in a bearing chamber formed in a pump body, a lubricant is filled in the bearing chamber, and leakage of the lubricant is prevented an oil seal installed inside the bearing chamber, and an auxiliary impeller for flowing lubricant in the opposite direction to the oil seal while rotating with the rotating shaft is further installed in the bearing chamber, and between the auxiliary impeller and the oil seal, an auxiliary impeller A negative pressure space is formed in which the pressure is reduced as the lubricant is sucked out by the auxiliary impeller during rotation of A pump having a leak-proof structure of a bearing lubricant is provided.

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Meanwhile, in the pump having a structure for preventing leakage of the bearing lubricant, a pressure outlet for guiding the internal air of the bearing chamber to be discharged to the outside of the bearing chamber may be further formed in a member surrounding the bearing chamber.

On the other hand, in the pump having a leakage preventing structure of the bearing lubricant, the pressure outlet is made of a hole formed with a female screw therein, and an air vent that allows gas to be discharged but prevents liquid from being discharged can be screwed to the pressure outlet. have.

On the other hand, in the pump having a leakage preventing structure of the bearing lubricant, the pump includes a vertical axial pump, a vertical axial pump, a single suction volute pump, a double suction volute pump, an underwater axial flow pump, a submersible sand flow pump, and an underwater gate pump. , it may be composed of one of the submersible centrifugal pumps.

According to the present invention having the above characteristics, the auxiliary impeller installed inside the bearing chamber rotates together with the rotating shaft and flows the lubricant in the opposite direction of the oil seal, so that the lubricant can be effectively prevented from leaking to the outside through the oil seal. .

In addition, the auxiliary impeller installed inside the bearing chamber sucks the lubricant around the oil seal and discharges it in the bearing direction, and the lubricant discharged in the bearing direction flows through the circulation passage formed between the bearing and the bearing housing and circulates inside the bearing chamber. Therefore, it is possible to improve the lubrication effect of the bearing, and it is possible to prevent the lubricant from being hardened and fixed inside the bearing chamber.

1 is an internal structural diagram of a conventional submersible sand flow pump;
2 is a detailed view of part 'A';
3 is a structural diagram of a submersible sand flow pump equipped with a leak prevention structure according to the present invention;
4 is a detailed view of part 'A',
5 is a plan view of the auxiliary impeller according to the present invention;
6 is a structural diagram of a submersible axial flow pump to which the present invention is applied;
7 is a structural diagram of a double suction volute pump to which the present invention is applied;
8 is a structural diagram of a vertical axial flow pump to which the present invention is applied;
9 is a structural diagram of a vertical shaft pump to which the present invention is applied;
10 is a structural diagram of a submersible gate pump to which the present invention is applied;
11 is a structural diagram of a submersible centrifugal pump to which the present invention is applied.

Hereinafter, preferred embodiments of the present invention will be described in detail in conjunction with the accompanying drawings. In describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

3 is a structural diagram of a submersible sand flow pump provided with a leakage preventing structure according to the present invention, FIG. 4 is a detailed view of part 'A', and FIG. 5 is a plan structural diagram of an auxiliary impeller according to the present invention.

The pump according to the present invention includes a motor part 100 and a pump part 200 , and the motor part 100 and the pump part 200 may be integrally formed or formed in a structure separated from each other.

The motor part 100 includes a rotor 110 and a stator 120 , and the rotor 110 is connected to the pump part 200 and the impeller 210 through a rotation shaft 130 . Accordingly, when the motor part 100 is operated, the rotor 110 , the rotation shaft 130 , and the impeller 210 rotate.

On the other hand, one or more bearings (B) for supporting the rotation of the rotary shaft 130 are installed in the pump body forming the basic frame structure of the motor part 100 or the pump part 200, and bearings ( At least one of B) is installed in the bearing chamber 300 formed in the pump body, and a lubricant such as oil or grease is filled in the bearing chamber 300 .

In this way, the bearing chamber 300 in which the bearing B is accommodated and the lubricant is filled is in the bearing housing 310 and the cover 320 coupled to the bearing housing 310 to close the opening of the bearing housing 310 . and an oil seal 330 for preventing leakage of lubricant is installed on the cover 320 .

Meanwhile, in FIG. 4 , the upper cover 321 is installed on the upper part of the bearing housing 310 , the lower cover 322 is installed on the lower part of the bearing housing 310 , and the lubricant is applied to the lower cover 322 and the rotation shaft 130 . ) to prevent leakage between the oil seal 330 is shown in the structure installed in the lower cover 322.

In addition, the pump according to the preferred embodiment of the present invention further includes an auxiliary impeller 340 for flowing the lubricant in the opposite direction of the oil seal 330 while rotating together with the rotation shaft 130 inside the bearing chamber 300 .

The auxiliary impeller 340 consists of a plurality of impellers 210 bent in the form of an arc on one side of the circular shroud 341 and the vanes 342 are formed to protrude, and the rotation shaft 130 passes through the center. It is arranged, and is coupled to the rotation shaft 130 through the key is configured to rotate together with the rotation shaft 130 .

This auxiliary impeller 340 is disposed to be positioned between the bearing (B) and the oil seal 330 in the bearing chamber 300, and while rotating with the rotating shaft 130, sucks the lubricant around the rotating shaft 130 and Discharged in the centrifugal force direction, the lubricant around the rotary shaft 130 located in the oil seal 330 direction is sucked and discharged, and the lubricant discharged by the rotation of the auxiliary impeller 340 rides on the inner surface of the bearing chamber 300 and the bearing (B) is configured to flow around the periphery.

Meanwhile, in the case of the pump according to the preferred embodiment of the present invention, a negative pressure space 350 is formed between the auxiliary impeller 340 and the oil seal 330 , and the negative pressure space 350 is filled with a lubricant, and the rotation shaft 130 ) and the auxiliary impeller 340 rotate, the pressure is reduced while the lubricant in the negative pressure space 350 is sucked out by the auxiliary impeller 340 .

As such, by forming the negative pressure space 350 around the oil seal 330 , it is possible to more effectively prevent the lubricant from leaking through the oil seal 330 .

Meanwhile, a circulation passage 360 through which the lubricant flowing by the auxiliary impeller 340 can circulate around the bearing B is formed around the bearing B.

In the circulation passage 360, the lubricant flowing from the auxiliary impeller 340 in the bearing direction by the rotation of the auxiliary impeller 340 passes through the space between the bearing housing 310 and the bearing B to the other of the bearing B. It is formed between the outer circumference of the bearing B and the bearing housing 310 so as to be able to flow to the side (a side not facing the auxiliary impeller 340 ).

This circulation passage 360 may be formed by allowing the outer ring of the bearing B to be spaced apart from the bearing housing 310, and the outer ring of the bearing B may be supported on the bearing housing 310 by a separate support structure. have.

On the other hand, the bearing housing 310 or the cover 320 forming the bearing chamber 300 has a pressure outlet 370 for discharging the air inside the bearing chamber 300 to the outside so that the lubricant can flow more actively. It is formed, and the pressure outlet 370 is preferably formed to be positioned in the opposite direction to the oil seal 330 .

For example, when the oil seal 330 is installed in the lower cover 322 as shown in FIG. 4 , the pressure outlet 370 is formed in the upper cover 321 .

According to the pressure outlet 370 as described above, the air pushed out due to the flow of the lubricant while the lubricant flows inside the bearing chamber 300 by the rotation of the auxiliary impeller 340 is released through the pressure outlet 370 to the outside. By discharging the lubricating material, the air in the bearing chamber 300 is prevented from acting as a resistive element that obstructs the flow of the lubricant, thereby enabling a smoother flow of the lubricant.

On the other hand, an air vent 380 for preventing the lubricant from being discharged through the pressure outlet 370 together with the air may be further installed in the pressure outlet 370 .

To this end, a female screw is formed inside the pressure outlet 370, and a male screw fastened to the female screw is formed in the air vent 380, so that the air vent 380 can be installed in the pressure outlet 370 in a separable structure. .

At this time, the air vent 380 may be configured to allow the gas to be discharged, but to prevent the liquid from being discharged, and the air vent 380 includes a float floating by the liquid flowing into the interior of the float when the liquid is introduced. It may be composed of a known air vent configured to close the gas outlet while floating.

The pump of the present invention configured as described above may be configured as one of a vertical axial pump, a vertical axial pump, a single suction volute pump, a double suction volute pump, an underwater axial flow pump, a submersible sand flow pump, an underwater gate pump, and an underwater centrifugal pump. 3 shows the structure of the submersible sand flow pump according to the present invention, FIG. 6 shows the structure of the submersible axial flow pump according to the present invention, and FIG. 7 shows the double suction volute pump according to the present invention. The structure is shown, Fig. 8 shows the structure of the vertical axial axial pump according to the present invention, Fig. 9 shows the structure of the vertical axis axial pump, and Fig. 10 shows the structure of the submersible gate pump according to the present invention is shown, and the structure of the submersible centrifugal pump according to the present invention is shown in FIG. 11 .

On the other hand, in the pump of the present invention, the auxiliary impeller 340 installed on the rotating shaft 130 is installed on the rotating shaft 130 in the process of sucking and discharging the fluid while the rotating shaft 130 and the impeller 210 rotate by the operation of the motor part 100 together. It rotates, and the lubricant filled in the bearing chamber 300 flows by the rotation of the auxiliary impeller 340 .

Since the auxiliary impeller 340 flows the lubricant in the opposite direction to the oil seal 330 located around it, the lubricant flows in the oil seal 330 direction to prevent leakage between the oil seal 330 and the rotating shaft 130. be able to

Moreover, the auxiliary impeller 340 sucks and discharges the lubricant in the negative pressure space 350, and in this process, the negative pressure space 350 is maintained at a relatively low pressure, so that the leakage of the lubricant can be more effectively prevented. do.

On the other hand, since the lubricant flowing by the auxiliary impeller 340 circulates around the bearing B, the lubrication effect of the bearing B can be further improved.

As described above, in the pump according to the present invention, the auxiliary impeller 340 is installed in the bearing chamber 300 in which the bearing B is installed, and the auxiliary impeller 340 is the auxiliary impeller 340. As it is configured to circulate around the bearing (B) after sucking the lubricant in the negative pressure space 350 formed between the oil seal 330 and the oil seal 330 , the lubricant leaks through between the oil seal 330 and the rotating shaft 130 . It is a very useful invention that can prevent and improve the lubrication effect of the bearing (B).

The present invention is not limited to the specific preferred embodiments described above, and without departing from the gist of the present invention as claimed in the claims, anyone with ordinary skill in the art to which the invention pertains can make various modifications. Of course, such modifications are intended to be within the scope of the claims.

<Explanation of symbols for main parts of the drawing>
130: rotation shaft 210: impeller
300: bearing chamber 330: oil seal
340: auxiliary impeller 350: sound pressure space
360: circulation passage 370: pressure outlet
380: air vent

Claims (6)

An impeller 210 for sucking and discharging fluid while rotating is disposed therein, and the impeller 210 is connected to a rotating shaft 130 extending from the motor to rotate together with the rotating shaft 130 to pump the fluid. in,
At least one of the bearings (B) supporting the rotation shaft 130 is accommodated in the bearing chamber 300 formed in the pump body, and a lubricant is filled in the bearing chamber 300 to prevent leakage of the lubricant. The oil seal 330 is made to be installed inside the bearing chamber 300,
An auxiliary impeller 340 for flowing the lubricant in the opposite direction of the oil seal 330 while rotating together with the rotation shaft 130 is further installed in the bearing chamber 300 ,
Between the auxiliary impeller 340 and the oil seal 330, a negative pressure space 350 is formed in which the pressure is reduced as the lubricant is sucked out by the auxiliary impeller 340 when the auxiliary impeller 340 rotates,
A pump having a structure for preventing leakage of bearing lubricant, characterized in that between the outer circumference of the bearing (B) and the bearing housing (310), a circulation passage (360) through which the lubricant flowing by the auxiliary impeller (340) passes is formed.
delete delete The method according to claim 1,
A structure for preventing leakage of a bearing lubricant, characterized in that a pressure outlet 370 guiding the internal air of the bearing chamber 300 to be discharged to the outside of the bearing chamber 300 is further formed in a member surrounding the bearing chamber 300 a pump with
5. The method according to claim 4,
The pressure outlet 370 is made of a hole with a female thread therein, and an air vent 380 that allows gas to be discharged but prevents liquid from being discharged is screwed to the pressure outlet 370. Bearing lubricant A pump with a leak-proof structure of
The method according to claim 1,
The pump is one of a vertical axial flow pump, a vertical axial flow pump, a single suction volute pump, a double suction volute pump, an underwater axial flow pump, a submersible sand flow pump, an underwater gate pump, and a submersible centrifugal pump. A pump with a leak-proof structure.

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