KR101370556B1 - Dual sealing structure for underwater pump - Google Patents

Abstract

The present invention relates to a dual sealing structure for an underwater pump, in which springs are respectively installed at upper and lower portions, thereby preventing infiltration of water into a motor at the upper portion despite the inflow of from a pump. The dual sealing structure comprises: a rotary shaft which axially penetrates a motor housing part and a pump housing part; a seal cover part which is located between the motor housing part and the pump housing part and fixed to the rotary shaft so as to allow the axial penetration of the rotary shaft; a first sealing part which is located between the motor housing part and the seal cover part and pressed toward the motor housing part by a first pressing part; and a second sealing part which is located between the pump housing part and the seal cover part and pressed toward the pump housing part by a second pressing part. According to the dual sealing structure for an underwater pump, the elastic springs as pressing members are respectively installed at the upper and lower portions to achieve a dual sealing structure, thereby preventing infiltration of water into the motor at the upper portion despite the inflow of from the pump, so that the maintenance costs of the underwater pump can be saved. [Reference numerals] (AA) Oil

Description

Dual Sealing Structure for Underwater Pump

The present invention relates to a double sealing structure for a submersible pump, and more particularly, a spring is mounted on each of the upper and lower parts to form a double sealing structure so that water is prevented from entering the motor of the upper part even if water is introduced from the pump. A double seal structure for a pump.

In general, a mechanical seal is installed between the pump housing part 30 and the motor housing part 10 of the submersible pump, and the mechanical seal has a motor housing part 10 and a pump housing part as shown in FIG. 1. The first sealing part 70 in close contact with the motor housing part 10 by passing through the rotation shaft 20 provided through the 30 and the rotation shaft 20 in close contact with the pump housing part 30. A second sealing part 90 and an elastic spring-type pressing part 50 provided between the first sealing part 70 and the second sealing part 90 to provide a pressing force in the vertical direction. do.

Lubricating oil is enclosed in the oil chamber of the mechanical seal, and the amount of lubricating oil to be sealed is a rate of expansion due to heat generation of the sliding surfaces of the first sealing part 70 and the second sealing part 90 or heat generation of the motor during rotation. In anticipation, it is generally about 80% of the volume in the oil chamber, and has an air layer on top of the oil chamber.

The conventional mechanical seal has a structure such that any one of the first sealing part 70 or the second sealing part 90 is damaged by the foreign material and the abnormal pressure of the pump, so that the tension of the elastic spring that is the pressing part 50 is increased. When this is loosened, water may be introduced into the oil chamber, and oil and water in the oil chamber may be mixed and introduced into the motor, resulting in high maintenance costs due to the failure of the motor.

Republic of Korea Patent Application Publication No. 10-2002-0061498

The present invention has been made in order to solve the above problems, the elastic spring as the pressing portion is mounted on each of the upper and lower portions to form a double sealing structure prevents water from flowing into the upper motor even if water is introduced from the pump underwater It is to provide a double sealing structure for submersible pumps that can save the maintenance cost of the pump.

Double sealing structure for submersible pump of the present invention for achieving the above object is a rotating shaft provided through the motor housing and the pump housing in the axial direction; A seal cover part disposed between the motor housing part and the pump housing part and fixed to the rotation shaft by allowing the rotation shaft to penetrate in the axial direction; A first sealing part disposed between the motor housing part and the seal cover part and pressed by the first pressing means toward the motor housing part; And a second sealing part positioned between the pump housing part and the seal cover part and pressed by the second pressing means toward the pump housing part.

The first sealing part may include: a first stator part positioned below the motor housing part and fixed to the motor housing part to allow the rotation shaft to penetrate in the axial direction; A first rotor part positioned below the first stator part and fixed to the rotation shaft so that the rotation shaft penetrates in the axial direction and is in sliding contact with the first stator part; And a first pressing part positioned on the seal cover part to allow the rotation shaft to penetrate in the axial direction and pressurizing the first rotor part toward the first stator part, wherein the second sealing part includes: A second stator part positioned at an upper portion of a pump housing part and fixed to the pump housing part to allow the rotation shaft to penetrate in an axial direction; A second rotor part positioned on an upper portion of the second stator part and fixed to the rotation shaft by penetrating in the axial direction, the second rotor part being in sliding contact with the second stator part; And a second pressing part positioned below the seal cover part to allow the rotation shaft to penetrate in the axial direction, and pressurize the second rotor part toward the second stator part.

A first packing part is inserted into the gap formed between the motor housing part and the first stator part to allow the rotation shaft to penetrate in the axial direction; The second packing part may be inserted by allowing the rotation shaft to penetrate in the axial direction with a gap formed between the pump housing part and the second stator part.

A first bellow portion in which the rotating shaft penetrates in the axial direction and is in close contact with a lower portion of the first rotor part, and an end thereof extends in the axial direction and is in close contact with the rotating shaft; A second bellow part may be provided to be in close contact with an upper portion of the second rotor part so that the rotating shaft penetrates in the axial direction, and an end thereof extends in the axial direction.

A first retainer portion provided to surround the first rotor portion and the first bellow portion in a radially outer side such that the rotation shaft penetrates in the axial direction; A second retainer part may be provided to surround the second rotor part and the second bellow part in a radially outer side such that the rotation shaft penetrates in the axial direction.

A first driver ring is inserted between the first bellows portion and the first retainer portion such that the rotating shaft penetrates in the axial direction; A second driver ring may be inserted between the second bellow part and the second retainer part so that the rotation shaft penetrates in the axial direction.

One side of the first pressing part contacts the seal cover part and the other side contacts the first retainer part; One side of the second pressing part may contact the seal cover part, and the other side may contact the second retainer part.

The seal cover portion may have a first extension portion and a second extension portion extending from the outer circumferential surface to the axially outer side, respectively, and a fitting groove portion formed concave from the radially outer side to the radially inner side in the center of the outer circumferential surface may be formed in the circumferential direction.

The first sealing part is located in the lower portion of the motor housing portion and the rotating shaft is penetrated in the axial direction is fixed to the motor housing portion and the first fixing groove is formed in the circumferential direction concave radially inward from the outer radial direction 1 stator part; Located in the lower portion of the first stator, the rotating shaft is provided to be fixed to the rotating shaft so as to penetrate in the axial direction, and the sliding contact with the first stator portion, the first rotary groove concave radially outward from the radial direction inside A first rotor part formed in an additional circumferential direction; And a first pressurizing part disposed above the seal cover part and provided in a circumferential direction to pressurize the first rotor part toward the first stator part, wherein the second sealing part includes the pump housing part. A second stator portion positioned at an upper portion thereof and fixed to the pump housing to allow the rotation shaft to penetrate in an axial direction, and having a second fixing groove concave radially inward from a radially outer side; A second rotary groove positioned on an upper part of the second stator part and fixed to the rotary shaft by penetrating in the axial direction, and sliding contact with the second stator part, and recessed radially outward from a radially inner side; A second rotor portion formed in an additional circumferential direction; And a second pressing part disposed below the seal cover part and provided in a circumferential direction to press the second rotor part toward the second stator part.

O-rings may be provided in the first fixing groove, the first rotating groove, the second fixing groove, and the second rotating groove.

The seal cover portion is formed with a first extension portion and a second extension portion extending from the outer circumferential surface, respectively, in the circumferential direction at the center of the outer circumferential surface, the fitting grooves formed concave from the radially outer side to the radially inner side in the circumferential direction. A plurality of first pressing grooves and second pressing grooves concave in the axial direction from the outer side in the axial direction may be formed in the lower surface.

The first extension part is in close contact with the first rotor part and the second extension part is in close contact with the second rotor part; One side of the first pressing part is inserted into the first pressing groove and the other side is in close contact with the first rotor part, one side of the second pressing part is inserted into the second pressing groove and the other side is in close contact with the second rotor part. Can be.

A clamping ring is installed on the upper surface of the pump housing to allow the rotating shaft to pass therethrough; One end is coupled to the clamp ring, the other end may be provided with a guide pin portion inserted into the fitting groove.

The guide pin portion may be provided in plurality in the circumferential direction.

According to the double sealing structure for the submersible pump of the present invention as described above, the elastic spring which is the pressing portion is mounted on the upper and lower portions respectively, so that the double sealing structure is made so that the water is introduced into the upper motor even though the water is introduced from the pump. This prevents the maintenance cost of the submersible pump.

1 is a cross-sectional view showing a conventional sealing structure for a water pump,
2 is a cross-sectional view showing a double sealing structure for a submersible pump according to a first embodiment of the present invention,
3 is a cross-sectional view showing a double sealing structure for a submersible pump according to a second embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

In the following description, the horizontal direction of FIG. 2 is referred to as the 'radial direction', the vertical direction is referred to as the 'axial direction', and the direction toward the center of the rotation axis 900 in the axial direction is referred to as the 'axial direction inner' and the rotation axis 900. The direction toward both ends of the is called 'axially outward', the direction toward the rotation axis 900 in the radial direction is referred to as 'radial inward', and the direction away from the rotation axis 900 is referred to as 'radially outward'.

2 is a cross-sectional view showing a double sealing structure for a submersible pump according to a first embodiment of the present invention.

As shown in FIG. 2, the dual sealing structure for the submersible pump according to the first embodiment of the present invention includes a motor housing part 100 and a pump (not shown) provided on the side of the motor (not shown). The pump housing part 200 on the side, the rotating shaft 900 provided through the motor housing part 100 and the pump housing part 200 in the axial direction, the seal cover part 800, and the first sealing part. 300, the second sealing part 500 is configured to be included.

An oil chamber is formed between the motor housing part 100 and the pump housing part 200, and about 80% of the lubricant G is enclosed in the oil chamber, and the other space is formed by the air layer A. do.

The motor housing part 100 has a first annular groove portion 130 having a lower concave outward in an axial direction, and a circumferential wall portion 110 protrudes in an axial direction to an outer circumferential surface of the first annular groove portion 130. .

The pump housing part 200 is formed with a second annular groove portion 230 which is concave outward in the axial direction.

The seal cover part 800 is positioned between the motor housing part 100 and the pump housing part 200 and is fixed to the rotation shaft 900 by allowing the rotation shaft 900 to penetrate in the axial direction.

The seal cover 800 may be fixed to the rotating shaft 900 through the screw fastening means (S) that is screwed in the radial direction to the rotating shaft (900).

The seal cover part 800 has a first extension portion 830 and a second extension portion 850 extending from the outer circumferential end to the upper and lower axial directions, respectively, and are recessed radially inward in the center of the outer circumferential surface. The fitting groove 810 is formed in the circumferential direction.

The first sealing part 300 is located between the motor housing part 100 and the seal cover part 800 and pressurized toward the motor housing part 100 by a first pressing means. The first rotor part 320, the first rotor part 320, the first bellows part 330, the first retainer part 340, and the first driver ring 360 are included. It is configured.

The first stator 310 is positioned in the first annular groove 130 below the motor housing 100 and is fixed to the motor housing 100 by allowing the rotation shaft 900 to penetrate in the axial direction. do.

A first packing part 150 of a flexible material is inserted into the gap between the motor housing part 100 and the first stator part 310 so that the rotation shaft 900 penetrates in the axial direction.

The first stator part 310 may be in close contact with the motor housing part 100 due to the first packing part 150.

The first rotor part 320 is positioned below the first stator part 310, is fixed to the rotation shaft 900 by penetrating the rotation shaft 900 in the axial direction, and the first stator part ( 310 is in sliding contact.

The first pressing part 350 is positioned between the seal cover part 800 and the first rotor part 320, and is installed to penetrate the rotation shaft 900 in the axial direction, and the first rotor part 320. ) Is pressed toward the first stator 310.

Therefore, the lower surface of the first stator part 310 and the upper surface of the first rotor part 320 are in sliding contact in a state in which it is pressed and in close contact.

The first bellows portion 330 allows the rotary shaft 900 to penetrate in the axial direction, and one side thereof is in close contact with the lower portion of the first rotor unit 320, and the other side thereof extends in the axial direction and the rotary shaft 900. It is provided in close contact.

The first retainer part 340 is provided to surround the first rotor part 320 and the first bellows part 330 in the radially outer side such that the rotation shaft 900 penetrates in the axial direction.

The first driver ring 360 has a ring shape and is provided between the first bellows 330 and the first retainer 340 to allow the rotation shaft 900 to penetrate in the axial direction.

The second sealing part 500 is located between the pump housing part 200 and the seal cover part 800 and pressurized toward the pump housing part 200 by a second pressing means. 510, a second rotor part 520, a second pressurizing part 550, a second bellow part 530, a second retainer part 540, and a second driver ring 560 are included. It is configured.

The second stator 510 is positioned in the second annular groove 230 on the pump housing 100 and is fixed to the pump housing 200 by allowing the rotation shaft 900 to penetrate in the axial direction. do.

A second packing part 250 of a flexible material is inserted into the gap between the pump housing part 200 and the second stator part 510 so that the rotating shaft 900 penetrates in the axial direction.

The second stator part 510 may be in close contact with the pump housing part 200 due to the second packing part 250.

The second rotor part 520 is positioned above the second stator part 510, and is fixed to the rotation shaft 900 by penetrating the rotation shaft 900 in the axial direction, and the second stator part ( 510 is in sliding contact.

The second pressing part 550 is located between the seal cover part 800 and the second rotor part 520, and is installed such that the rotation shaft 900 penetrates in the axial direction, and the second rotor part 520. ) Is pressed toward the second stator 510.

Therefore, the upper surface of the second stator part 510 and the lower surface of the second rotor part 520 are in sliding contact with each other while being pressed and in close contact.

An elastic spring may be used for the first pressing part 350 and the second pressing part 550.

The second bellows portion 530 allows the rotation shaft 900 to penetrate in the axial direction, and one side thereof is in close contact with the upper portion of the second rotor portion 520, and the other side thereof extends in the axial direction and the rotation shaft 900. It is provided in close contact.

The second retainer portion 540 is provided to surround the second rotor portion 520 and the second bellows portion 530 in the radially outer side such that the rotation shaft 900 penetrates in the axial direction.

The second driver ring 560 is provided between the second bellows 530 and the second retainer 540 so that the rotation shaft 900 penetrates in the axial direction.

A ring-shaped clamp ring 270 is installed on the upper surface of the pump housing 200 to allow the rotation shaft 900 to pass therethrough.

The clamp ring 270 is fixedly coupled through the fastening means 280 on the upper surface of the pump housing 200.

A guide pin portion P is provided between the clamp ring 270 and the seal cover portion 800.

One end of the guide pin P is coupled to the upper portion of the clamp ring 270, and the other end of the guide pin P is inserted into the fitting groove 810.

By adjusting the length of the guide pin portion (P) may be such that the seal cover portion 800 is located in the center of the rotating shaft 900 in the axial direction between the motor housing 100 and the pump housing 200. .

When the seal cover part 800 is positioned at an intermediate point of the rotation shaft 900 through the guide pin part P, the seal cover part 800 is fixedly coupled to the rotation shaft 900 through the screw fastening means S. .

The guide pin portion P may be provided in plurality in the circumferential direction.

When the seal cover part 900 is located at the center in the axial direction on the rotation shaft 900, the pressing force and the second sealing part 500 that are pressed from the first sealing part 300 to the motor housing part 100. The pressing force pressurized by the pump housing 200 becomes equal.

Therefore, the adhesion between the first stator part 310 and the first rotor part 320 in the first sealing part 300 and the second stator part 510 and the second rotor part ( The adhesion between the 520 is equal.

In addition, the first sealing part 300 or the second sealing part 500 is provided on the basis of the seal cover part 800 so that any one of the first sealing part 300 or the second sealing part 500 is provided. Even if one breaks, one of the two remains in close contact due to the pressing force.

Therefore, if the first sealing part 300 is damaged and the pressure of the second sealing part 500 is maintained, the inflow of water from the pump may be blocked into the oil chamber, and the second sealing part 500 may be damaged. If the pressurization state of the first sealing part 300 is maintained, even if water is introduced into the oil chamber from the pump, it is impossible to introduce water into the motor.

3 is a cross-sectional view showing a double sealing structure for a submersible pump according to a second embodiment of the present invention.

In the dual sealing structure for the submersible pump according to the second embodiment of the present invention, the remaining components except for the first sealing part 300, the second sealing part 500 and the seal cover part 700 in the first embodiment are the same. Therefore, the description of the same components and actions will be omitted.

As shown in FIG. 3, the double seal structure for the submersible pump according to the second embodiment of the present invention includes the first extension part 730 and the first extension part 730 extending outward from the outer circumferential surface, respectively. The two extension parts 750 are formed, and the fitting groove part 710 is formed in the circumferential direction at the center of the outer circumferential surface to be concave radially inward.

A plurality of first pressing grooves 770 and second pressing grooves 790 which are concave from the outer side in the axial direction to the inner side in the axial direction are formed in the upper and lower surfaces of the seal cover part 700, respectively.

The first pressing groove 770 and the second pressing groove 790 are formed in the circumferential direction with equal intervals.

The first sealing part 400 includes a first stator part 410, a first rotor part 420, and a first pressing part 450, and the second sealing part 600 includes a second stator part ( 610, a second rotor part 620, and a second pressurizing part 650 are included.

The first stator 410 is positioned in the first annular groove 130 of the motor housing 100 and fixed to the motor housing 100 by allowing the rotation shaft 900 to penetrate in the axial direction. The first fixing groove 411 which is concave radially inward is formed in the circumferential direction.

The first fixing groove 411 is provided with a ring-shaped first fixed o-ring 413.

The first rotor part 420 is positioned below the first stator part 410, and is fixed to the rotation shaft 900 by allowing the rotation shaft 900 to penetrate in the axial direction, and the first stator part ( The first rotary groove 421 in sliding contact with the 410 and recessed radially outward is formed in the circumferential direction.

The first rotary groove 421 is provided with a ring-shaped first rotary o-ring 423.

The first extension part 730 extending outward from the outer circumferential surface of the seal cover part 700 in the axial direction is in close contact with the side surface of the first rotor part 420.

The first pressing part 450 is positioned above the seal cover part 700, and is provided in a plurality in a circumferential direction with the rotation axis 900 as a center axis to provide the first rotor part 420 with the first rotor part 420. Pressurized toward the stator part 410.

One side of the first pressing unit 450 is inserted into the first pressing groove 770 and the other side is in close contact with the lower portion of the first rotor unit 420.

One side of the first pressing part 450 is provided to be inserted into the first pressing groove 770, so that the first pressing part 450 may be in place without being separated.

The second stator 610 is located in the second annular groove 230 of the pump housing 200 and is fixed to the pump housing 200 by allowing the rotation shaft 900 to penetrate in the axial direction. The second fixing groove 611, which is concave radially inward, is formed in the circumferential direction.

The second fixing groove 611 is provided with a ring-shaped second fixed o-ring 613.

The second rotor part 620 is positioned above the second stator part 610 and is fixed to the rotation shaft 900 by allowing the rotation shaft 900 to penetrate in the axial direction. The second rotary groove 621 which is in sliding contact with the 610 and is recessed radially outward is formed in the circumferential direction.

The second rotary groove 621 is provided with a ring-shaped second rotary o-ring 623.

The second extension part 750 extending from the outer circumferential surface of the seal cover part 700 in the axial direction is in close contact with the side of the second rotor part 620.

The second pressing part 650 is disposed under the seal cover part 700, and is provided in plural in the circumferential direction with the rotation axis 900 as a center axis to provide the second rotor part 620 with the second. Pressurized toward the stator 610.

 One side of the second pressing part 650 is inserted into the second pressing groove 790 and the other side is in close contact with the upper surface of the second rotor part 620.

Since one side of the second pressing part 650 is provided to be inserted into the second pressing groove 790, the second pressing part 650 may be in place without being separated.

An elastic spring may be used for the first pressing part 450 and the second pressing part 650.

In the above description, the present invention has been described with reference to preferred embodiments, but the present invention is not necessarily limited thereto, and a person having ordinary skill in the art to which the present invention pertains does not depart from the technical spirit of the present invention. It will be readily appreciated that various substitutions, modifications and variations can be made.

100: motor housing 200: pump housing
300: first sealing portion 350: first pressing portion
500: second sealing part 550: second pressing part
800: seal cover 900: rotating shaft

Claims (14)

A rotating shaft provided through the motor housing and the pump housing in the axial direction;
A seal cover part disposed between the motor housing part and the pump housing part and fixed to the rotation shaft by allowing the rotation shaft to penetrate in the axial direction;
A first sealing part disposed between the motor housing part and the seal cover part and pressed by the first pressing means toward the motor housing part; And
Located between the pump housing and the seal cover portion and comprises a second sealing portion pressed by the second pressing means toward the pump housing,
In the center of the outer circumferential surface of the seal cover portion is formed in the circumferential direction the fitting groove formed concave from the radially outer side to the radially inner side;
A clamping ring is installed on the upper surface of the pump housing to allow the rotating shaft to pass therethrough;
One end is coupled to the clamp ring, the other end is a double sealing structure for a submersible pump, characterized in that provided with a guide pin portion inserted into the fitting groove. The apparatus of claim 1, wherein the first sealing part comprises: a first stator part positioned below the motor housing part and fixed to the motor housing part to allow the rotation shaft to penetrate in an axial direction;
A first rotor part positioned below the first stator part and fixed to the rotation shaft so that the rotation shaft penetrates in the axial direction and is in sliding contact with the first stator part; And
Located in the upper portion of the seal cover portion, the rotating shaft is passed through the axial direction, and comprises a first pressing portion for pressing the first rotor portion toward the first stator portion,
The second sealing part may include: a second stator part positioned on an upper portion of the pump housing part and fixed to the pump housing part so that the rotation shaft penetrates in the axial direction;
A second rotor part positioned on an upper portion of the second stator part and fixed to the rotation shaft by penetrating in the axial direction, the second rotor part being in sliding contact with the second stator part; And
Located in the lower portion of the seal cover portion, the rotary shaft penetrates in the axial direction, the second sealing portion for a submersible pump, characterized in that it comprises a second pressing portion for pressing the second rotor portion toward the second stator portion . The first packing part of claim 2, wherein the rotation shaft penetrates in the axial direction with a gap formed between the motor housing part and the first stator part.
And a second packing part is inserted into the gap formed between the pump housing part and the second stator part so that the rotating shaft penetrates in the axial direction. 3. The apparatus of claim 2, further comprising: a first bellow portion configured to allow the rotation shaft to penetrate in the axial direction, and to be in close contact with a lower portion of the first rotor part, and an end portion thereof extends in the axial direction and is in close contact with the rotation shaft;
The second sealing portion for the submersible pump, characterized in that the rotary shaft penetrates in the axial direction and is in close contact with the upper portion of the second rotor portion, the end portion is extended in the axial direction and provided in close contact with the rotating shaft. . 5. The apparatus of claim 4, further comprising: a first retainer portion provided to surround the first rotor portion and the first bellow portion in a radially outer side such that the rotation shaft penetrates in the axial direction;
And a second retainer portion provided to surround the second rotor portion and the second bellow portion in a radially outer side such that the rotation shaft penetrates in the axial direction. The method according to claim 5, wherein the first driver ring is inserted between the first bellows portion and the first retainer portion so that the rotating shaft penetrates in the axial direction;
And a second driver ring is inserted between the second bellows portion and the second retainer portion to allow the rotation shaft to penetrate in the axial direction. The method of claim 6, wherein one side of the first pressing portion is in contact with the seal cover portion, the other side is in contact with the first retainer portion;
One side of the second pressurization portion is in contact with the seal cover portion, the other side is in contact with the second retainer portion, the double sealing structure for the submersible pump. The double sealing structure of claim 1, wherein the seal cover portion has a first extension portion and a second extension portion extending from an outer circumferential surface thereof in an axially outward direction. The first fixing groove of claim 1, wherein the first sealing part is positioned below the motor housing part and is fixed to the motor housing part so that the rotation shaft penetrates in the axial direction and is concave radially inward from the outside in the radial direction. A first stator part formed in the circumferential direction;
Located in the lower portion of the first stator, the rotating shaft is provided to be fixed to the rotating shaft so as to penetrate in the axial direction, and the sliding contact with the first stator portion, the first rotary groove concave radially outward from the radial direction inside A first rotor part formed in an additional circumferential direction; And
Located in the upper portion of the seal cover portion, provided with a plurality in the circumferential direction is configured to include a first pressing portion for pressing the first rotor portion toward the first stator portion,
The second sealing part is located in the upper portion of the pump housing and the rotating shaft is axially penetrating the second fixed groove is provided in the pump housing and fixed in the circumferential direction in the radially inward from the radially outer side 2 stator part;
A second rotary groove positioned on an upper part of the second stator part and fixed to the rotary shaft by penetrating in the axial direction, and sliding contact with the second stator part, and recessed radially outward from a radially inner side; A second rotor portion formed in an additional circumferential direction; And
Located in the lower portion of the seal cover portion, provided with a plurality in the circumferential direction is a double sealing structure for a submersible pump, characterized in that it comprises a second pressing portion for pressing the second rotor portion toward the second stator portion. The double sealing structure of claim 9, wherein the first fixing groove, the first rotating groove, the second fixing groove, and the second rotating groove are provided with an O-ring. The method according to claim 9, wherein the seal cover portion is formed with a first extension portion and a second extension portion extending from the outer peripheral surface in the axial direction, respectively, and the first pressing groove and the second concave in the axial direction in the axial direction on the upper and lower surfaces Double sealing structure for submersible pump, characterized in that a plurality of pressure grooves each formed. The method of claim 11, wherein the first extension portion is in close contact with the first rotor portion, the second extension portion is in close contact with the second rotor portion;
One side of the first pressing part is inserted into the first pressing groove and the other side is in close contact with the first rotor part, one side of the second pressing part is inserted into the second pressing groove and the other side is in close contact with the second rotor part. Double sealing structure for submersible pump, characterized in that. delete The double sealing structure of claim 1, wherein the guide pin portion is provided in circumferential direction.

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