KR102558700B1 - Magnet vertical multi-stage centrifugal pump - Google Patents

Abstract

The present invention relates to a magnet vertical multistage centrifugal pump in which power of a motor is transmitted to a pump shaft by applying a magnetic coupling to a vertical multistage centrifugal pump.
The magnet vertical multistage centrifugal pump according to the present invention includes a lower casing 10 having a suction port 11 and a discharge port 12 formed thereon, an outer sleeve 15 standing on the lower casing 10, an upper cover 20 mounted on the upper end of the outer sleeve 15, and a stage 30 including an impeller 31 and a diffuser 32 therein, multi-staged, The outer rotor 510 is mounted on the passage gap 17 formed between the stacked stages 30 and the outer sleeve 15, the shaft 35 passing through the center of the stacked stages 30 and coupled to the impeller 31 of the stage 30, the motor 40 disposed on the top of the upper cover 20, and the drive shaft 41 of the motor 40, and the inner rotor 520 on the top of the shaft 35. ) is mounted, and the first magnet assembly 515 of the outer rotor 510 and the second magnet assembly 525 of the inner rotor 520 are disposed to face each other, so that the motor 40 is driven by magnetic force. It is characterized in that it includes a magnetic coupling 50 that transmits power to the shaft 35.

Description

Magnet vertical multi-stage centrifugal pump {MAGNET VERTICAL MULTI-STAGE CENTRIFUGAL PUMP}

The present invention relates to a magnet vertical multistage centrifugal pump in which a magnetic coupling is applied to a vertical multistage centrifugal pump and the power of the motor is transmitted to the pump shaft by the magnetic coupling, and more particularly, an outer rotor is mounted on a drive shaft of the motor, an inner rotor is mounted on top of the pump shaft, and the first magnet assembly of the outer rotor and the second magnet assembly of the inner rotor are disposed to face each other, including a magnetic coupling for transmitting motor power to the shaft by magnetic force. It relates to a net vertical multistage centrifugal pump.

Korean Patent No. 10-1818075 (registered on January 8, 2018) introduces "double sealing structure of vertical multi-stage pump".

The double sealing structure of the vertical multistage pump is provided with an impeller connected to a shaft of a motor in an impeller installation space connected to an inlet, and a discharge space formed around the impeller installation space is connected to an outlet, so that the first fluid sucked into the impeller installation space is discharged to the outlet; a seal sleeve coupled to an outer surface of the shaft between the impeller and the motor; a seal housing having a space for passing a second fluid formed on an outer circumferential surface of the seal sleeve, having an inlet and an outlet, having a first hollow part formed on an upper side and having an open lower end; a seal cover coupled to a lower end of the seal housing and having a second hollow portion formed in the center thereof; an upper mechanical seal including an upper first sealing member in contact with the outer surface of the seal sleeve, an upper second sealing member in contact with the inner surface of the first hollow portion, and an upper rotating ring in contact with the upper first and second sealing members, respectively; A lower mechanical seal including a lower first sealing member in contact with the outer surface of the seal sleeve, a lower second sealing member in contact with the inner surface of the second hollow portion, and a lower rotating ring in contact with the lower first and second sealing members, respectively.

The double sealing structure of the vertical multistage pump implements double mechanical seals to prevent leakage, but it can be improved to a structure in which fluid does not leak fundamentally.

Korean Patent Publication No. 10-2011-0089785 (published on August 9, 2011) introduces a “magnetic drive sealless pump”.

The magnetic drive sealless pump is a magnetic drive sealless pump having inlets and outlets provided on both sides of a casing, a bearing body coupled to one side of the casing, a frame coupled to one side of the bearing body, and rotating an impeller by using the interaction of internal and external magnetic drives accommodated inside the frame, wherein the insulation cover installed inside the frame to isolate the internal magnetic drive unit and the external magnetic drive unit from each other, and the rotational force of the internal magnetic drive unit is transmitted to the impeller, and the longitudinal direction A pump shaft having a flow path formed therethrough, and a backflow hose having one end coupled to one side of the outlet of the casing and the other end coupled through one side of the frame, wherein a portion of the fluid flowing from the suction port to the discharge port by the impeller passes through the backflow hose coupled to one side of the outlet, flows to the rear of the pump shaft through a gap formed between the inner circumferential surface of the insulating cover and the outer circumferential surface of the internal magnetic drive unit, and then is discharged along the longitudinal direction of the pump shaft. discharged into the mouth

However, the magnetically driven sealless pump has internal and external magnetic driving unit structures applied to a simple centrifugal pump rather than multi-stage, and a fluid cooling structure for cooling the internal and external magnetic driving units has a complicated structure.

Therefore, an object of the present invention is to include a magnetic coupling in which an outer rotor is mounted on a drive shaft of a motor, an inner rotor is mounted on an upper end of a pump shaft, and a first magnet assembly of the outer rotor and a second magnet assembly of the inner rotor are disposed to face each other to transmit power of the motor to the shaft by magnetic force. By including a magnetic coupling, there is no risk of leakage of pumping fluid by not using a mechanical seal, and by applying a magnetic coupling to a vertical multi-stage centrifugal pump, a magnet that can be used at plant sites and semiconductor sites. It is to provide a type multistage centrifugal pump.

Another object of the present invention is to provide a magnetic vertical multistage centrifugal pump that is easy to assemble and disassemble.

Another object of the present invention is to supply cooling water to the inside of the cover housing of the magnetic coupling, thereby preventing the temperature of the magnet assembly from being raised by the cooling water, thereby preventing the magnetic force of the magnet assembly from being lowered due to the temperature rise. It is to provide a vertical multi-stage centrifugal pump with a magnet.

The magnet vertical multistage centrifugal pump according to the present invention for achieving the above object is a lower casing having a suction port and a discharge port, an outer sleeve built on the lower casing, an upper cover mounted on an upper end of the outer sleeve, a stage stacked in multiple stages on the lower casing and including an impeller and a diffuser therein, a passage gap formed between the multistage stacked stages and the outer sleeve, and a shaft passing through the center of the stacked stages and coupled to the impeller of the stage, , The motor disposed on the upper cover, the outer rotor is mounted on the drive shaft of the motor, the inner rotor is mounted on the upper end of the shaft, the first magnet assembly of the outer rotor and the second magnet assembly of the inner rotor are disposed to face each other, characterized in that it includes a magnetic coupling for transmitting power of the motor to the shaft by magnetic force.

The magnetic coupling includes an outer rotor connected to the drive shaft of the motor, a first magnet assembly mounted on an inner circumferential surface of the outer rotor, an inner rotor mounted on an upper end of the shaft, a second magnet assembly mounted on an outer circumferential surface of the inner rotor, a non-magnetic cover housing disposed between the outer rotor and the inner rotor to cover the inner rotor, a stator bushing mounted on the upper cover and disposed around the shaft, and mounted on the lower surface of the inner rotor and mounted on the upper surface of the stator bushing It is characterized in that it comprises a rotor bushing rotatably seated.

In the outer rotor, a hollow part is formed in the cylindrical holder part, a shaft connection part is formed at the upper end of the holder part, a shaft hole is formed in the shaft connection part, the drive shaft of the motor is fitted into the shaft hole, and a first magnet assembly is mounted on the inner circumferential surface of the holder part,

The inner rotor is formed in a cylindrical shape, a soccer hole is formed in the center, the shaft is inserted into the soccer hole, a pocket is formed in the center of the upper surface, the upper fastening part of the shaft protrudes into the pocket through the soccer hole, and a nut is fastened to the upper fastening part of the shaft protruding into the pocket, a second magnet assembly is mounted on the outer circumferential surface, and a rotor bushing is coupled to the lower surface by bolts,

In the first magnet assembly and the second magnet assembly, a plurality of permanent magnets are alternately arranged with N poles and S poles in a ring shape, the S pole of the permanent magnet is disposed to correspond to the N of the permanent magnet, and the N pole of the permanent magnet is disposed to correspond to the S of the permanent magnet,

The cover housing is formed in a cylindrical cup shape in which the body is inverted, a lower opening is formed at the lower portion of the body, a support portion is formed around the lower end of the body, and a bolt is fastened to the upper cover through a pressing member. By pressing the support portion, the support portion is characterized in that the upper cover is compressed.

The upper cover includes a cylindrical portion seated on an upper end of the outer sleeve and a disk portion formed integrally with the cylindrical portion and disposed inside the cylindrical portion, a center hole through which a shaft passes is formed at the center of the disk portion, a first seating portion is formed around the center hole, a stator bushing is disposed on the first seating portion, a rotor bushing coupled to the lower surface of the inner rotor is seated on the upper surface of the stator bushing to be relatively rotatable, and the outer circumference of the first seating portion is formed. A second seating portion is formed on the second seating portion, and the supporting portion and the pressing member of the cover housing are disposed on the second seating portion.

The rotor bushing and the stator bushing are made of silicon carbide (silicon carbide) material having high wear resistance, and the wear resistance of the stator bushing is higher than that of the rotor bushing.

In addition, in the magnet vertical multistage centrifugal pump according to the present invention, the rotor bushing coupled to the lower surface of the inner rotor is seated on the stator bushing disposed in the first seating part of the upper cover, the second magnet assembly is mounted on the outer circumferential surface of the inner rotor, the upper fastening part of the shaft protrudes into the pocket through the hole of the inner rotor, and the nut is fastened to the upper fastening part of the shaft protruding into the pocket, so that the shaft is supported by the inner rotor, and the inner rotor is supported by the rotor bushing and the stator bushing It is rotatably supported on the upper cover through the cover housing, and the support part and the pressing member of the cover housing are mounted on the second seating part of the upper cover so that the cover housing covers the inner rotor, and the shaft connection part of the outer rotor is connected to the drive shaft of the motor. By wrapping the holder part of the cover housing, the first magnet assembly mounted on the inner circumferential surface of the holder part faces the second magnet assembly mounted on the outer circumferential surface of the inner rotor with the cover housing interposed therebetween.

One example of the magnetic vertical multistage centrifugal pump according to the present invention is characterized in that a fluid hole is formed in the upper cover, the pumped fluid flows into the cover housing through the fluid hole, and a gap is formed between the main body of the cover housing and the second magnet assembly of the inner rotor, so that the fluid flowing into the cover housing is supplied to the pocket of the inner rotor through the gap and also fills the inside of the cover housing.

The outer rotor is characterized in that a plurality of exhaust holes are formed in the cylindrical holder portion, and heat generated by the first magnet assembly and filled in the holder portion is discharged to the outside through the exhaust holes.

Another example of the magnet vertical multistage centrifugal pump according to the present invention is that the cooling pipe is disposed outside the outer sleeve, the lower end of the cooling pipe is connected to the discharge port of the lower casing, and the upper end of the cooling pipe is connected to the cover housing of the magnetic coupling, so that a part of the fluid discharged through the discharge port of the lower casing is supplied to the inside of the cover housing through the cooling pipe, and the fluid is cooled while passing through the cooling pipe so that the low-temperature fluid is filled inside the cover housing, and the low-temperature fluid is filled with the second magnet By cooling the assembly, it is characterized in that the temperature of the second magnet assembly is increased to prevent the magnetic force from being lowered.

Another example of the magnetic vertical multi-stage centrifugal pump according to the present invention is that the cooling water supply device is connected to the cover housing of the magnetic coupling through a supply pipe, the cooling water of the cooling water supply device is supplied to the cover housing through the supply pipe, the upper end of the discharge pipe is connected to the cover housing, and the lower end of the discharge pipe is connected to the inlet of the lower casing. By this, the cooling water supplied from the cooling water supply device to the cover housing through the supply pipe cools the second magnet assembly, and the heat of the second magnet assembly is absorbed to cool the high temperature It is characterized in that the water is discharged to the inlet of the lower casing through the discharge pipe.

As a result, the magnetic vertical multistage centrifugal pump according to the present invention does not use a mechanical seal, so there is no risk of pumping fluid leakage, and by applying a magnetic coupling to the vertical multistage centrifugal pump, it can be used at plant sites and semiconductor sites. It is very convenient to assemble and disassemble, and there is an effect of preventing the magnetic force of the magnet assembly from deteriorating.

1 is a cross-sectional view showing a magnet vertical multistage centrifugal pump according to the present invention.
FIG. 2 is an enlarged detailed view of the magnetic coupling of FIG. 1 .
FIG. 3 is an exploded cross-sectional view showing the disassembled magnetic coupling of FIG. 2 .
4 is a schematic view showing an example in which a first magnet assembly and a second magnet assembly are arranged.
5 is a cross-sectional view and a partially enlarged detailed view of a vertical multi-stage centrifugal pump with a magnet according to a first embodiment of the present invention for cooling a magnet assembly.
6 schematically shows a vertical multi-stage centrifugal pump with a magnet according to a second embodiment of the present invention for cooling a magnet assembly.
7 schematically shows a vertical multi-stage centrifugal pump with a magnet according to a third embodiment of the present invention for cooling a magnet assembly.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. This description is not intended to limit the present invention to specific embodiments, but should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. Similar reference numerals have been used for similar components while describing each figure, and unless otherwise defined, all terms used in this specification, including technical or scientific terms, have the same meaning as commonly understood by those skilled in the art to which the present invention belongs.

In this document, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

1, the magnet vertical multistage centrifugal pump according to the present invention includes a lower casing 10 having a suction port 11 and a discharge port 12, an outer sleeve 15 standing on the lower casing 10, an upper cover 20 mounted on the upper end of the outer sleeve 15, and a stage including an impeller 31 and a diffuser 32 inside 30), a passage gap 17 formed between the multi-stacked stages 30 and the outer sleeve 15, a shaft 35 penetrating through the center of the stacked stages 30 and to which the impeller 31 of the stage 30 is coupled, a motor 40 disposed above the upper cover 20, and an outer rotor 510 mounted on the driving shaft 41 of the motor 40, and at the top of the shaft 35 The inner rotor 520 is mounted, and the first magnet assembly 515 of the outer rotor 510 and the second magnet assembly 525 of the inner rotor 520 are disposed to face each other, so that the motor 40 is driven by magnetic force. It includes a magnetic coupling 50 that transmits power to the shaft 35.

As described above, in the magnetic vertical multistage centrifugal pump according to the present invention, the driving shaft 41 and the shaft 35 of the motor 40 are connected by the magnetic coupling 50, so that there is no risk of leakage of pumping fluid because it does not use a mechanical seal, which frequently leaks. By applying the magnetic coupling 50 to a vertical multistage centrifugal pump that can easily increase the pumping pressure by increasing the number of stacked stages 30, there is an advantage that it can be used at plant sites and semiconductor sites.

2 to 4, the magnetic coupling 50 includes an outer rotor 510 connected to the driving shaft 41 of the motor 40, a first magnet assembly 515 mounted on an inner circumferential surface of the outer rotor 510, an inner rotor 520 mounted on an upper end of the shaft 35, a second magnet assembly 525 mounted on an outer circumferential surface of the inner rotor 520, and an inner rotor A non-magnetic cover housing 530 disposed between the outer rotor 510 and the inner rotor 520 to cover the 520, a stator bushing 65 mounted on the upper cover 20 and disposed around the shaft 35, and a rotor bushing 60 mounted on the lower surface of the inner rotor 520 and rotatably seated on the upper surface of the stator bushing 65.

In the outer rotor 510, a hollow part 512 is formed in a cylindrical holder part 511, a shaft connection part 513 is formed at an upper end of the holder part 511, and a shaft hole 514 is formed in the shaft connection part 513. .

The inner rotor 520 is formed in a cylindrical shape, a soccer hole 521 is formed in the center, the shaft 35 is fitted into the soccer hole 521, a pocket 522 is formed in the center of the upper surface, the upper fastening portion 36 of the shaft 35 protrudes into the pocket 522 through the soccer hole 521, and the nut 37 is fastened to the upper fastening portion 36 of the shaft 35 protruding into the pocket 522. And, the second magnet assembly 525 is mounted on the outer circumferential surface, and the rotor bushing 60 is coupled to the lower surface by bolts 61.

Referring to FIG. 4, in the first magnet assembly 515 and the second magnet assembly 525, a plurality of permanent magnets 517 and 527 are alternately arranged with N poles and S poles in a ring shape, the S pole of the permanent magnet 527 is disposed to correspond to the N of the permanent magnet 517, and the N pole of the permanent magnet 527 is disposed to correspond to the S of the permanent magnet 517.

The cover housing 530 is formed in a cylindrical cup shape in which the main body 531 is inverted, a lower opening 532 is formed at the lower portion of the main body 531, a supporting portion 533 is formed around the lower end of the main body 531, and a bolt 535 is fastened to the upper cover 20 through a pressing member 534, so that the pressing member 534 presses the supporting portion 533, thereby pressing the supporting portion ( 533, the upper cover 20 is compressed.

Referring back to FIG. 2 , the upper cover 20 includes a cylindrical portion 21 seated on the upper end of the outer sleeve 15 and a disk portion 22 integrally formed with the cylindrical portion 21 and disposed inside the cylindrical portion 21, a center hole 23 through which the shaft 35 passes is formed at the center of the disk portion 22, and a first seating portion 24 around the center hole 23 Formed, the stator bushing 65 is disposed on the first seating portion 24, the rotor bushing 60 coupled to the lower surface of the inner rotor 520 is seated on the upper surface of the stator bushing 65 to be relatively rotatable, and the second seating portion 25 is formed around the outer circumference of the first seating portion 24, and the receiving portion 53 of the cover housing 530 on the second seating portion 25 3) and a pressing member 534 are disposed.

The rotor bushing 60 and the stator bushing 65 are made of silicon carbide (silicon carbide) with high wear resistance, and the wear resistance of the stator bushing 65 should be higher than that of the rotor bushing 60.

In the magnet vertical multistage centrifugal pump according to the present invention configured as described above, the rotor bushing 60 coupled to the lower surface of the inner rotor 520 is seated on the stator bushing 65 disposed on the first seating part 24 of the upper cover 20, the second magnet assembly 525 is mounted on the outer circumferential surface of the inner rotor 520, and the upper fastening part 36 of the shaft 35 is installed on the inner rotor 5 20) protrudes into the pocket 522 through the shaft hole 521, and the nut 37 is fastened to the upper fastening portion 36 of the shaft 35 protruding into the pocket 522, so that the shaft 35 is supported by the inner rotor 520, the inner rotor 520 is rotatably supported by the upper cover 20 through the rotor bushing 60 and the stator bushing 65, and the cover housing 530 is To cover the rotor 520, the supporting portion 533 and the pressing member 534 of the cover housing 530 are mounted on the second seating portion 25 of the upper cover 20, and the drive shaft 41 of the motor 40 The shaft connecting portion 513 of the outer rotor 510 is connected, and the holder portion 511 of the outer rotor 510 surrounds the cover housing 530 As a result, the first magnet assembly 515 mounted on the inner circumferential surface of the holder unit 511 faces the second magnet assembly 525 mounted on the outer circumferential surface of the inner rotor 520 with the cover housing 530 interposed therebetween.

As such, the vertical multistage centrifugal pump with magnets according to the present invention has the advantage of very convenient assembly and disassembly.

Referring to FIG. 5, in the vertical multistage centrifugal pump according to the first embodiment of the present invention for cooling the magnet assembly, a fluid hole 26 is formed in the upper cover 20, the pumped fluid flows into the cover housing 530 through the fluid hole 26, and a gap 540 is formed between the main body 531 of the cover housing 530 and the second magnet assembly 525 of the inner rotor 520. As a result, the fluid flowing into the cover housing 530 is not only supplied to the pocket 522 of the inner rotor 520 through the gap 540, but also fills the inside of the cover housing 530.

A plurality of the fluid holes 26 are disposed between the first seating portion 24 and the second seating portion 25 of the upper cover 20 .

In addition, the outer rotor 510 has a plurality of exhaust holes 516 formed on the circumferential surface of the cylindrical holder part 511, and the heat generated by the first magnet assembly 515 and filled in the holder part 511 is discharged to the outside through the exhaust hole 516.

The exhaust hole 516 is disposed above the first magnet assembly 515 in the holder part 511 and is tapered so that its diameter increases from the inner circumferential surface to the outer circumferential surface.

As described above, in the magnet vertical multistage centrifugal pump according to the first embodiment of the present invention, a part of the fluid pumped by the rotation of the shaft 35 and the impeller 31 fills the inside of the cover housing 530 through the fluid hole 26 of the upper cover 20, and the fluid cools the second magnet assembly 525 of the inner rotor 520, so that the temperature of the second magnet assembly 525 rises and the magnetic force decreases. prevent it from becoming In addition, since the heat generated by the first magnet assembly 515 and filled in the holder part 511 is discharged through the exhaust hole 516, the temperature of the first magnet assembly 515 can be prevented from rising, and the magnetic force of the first magnet assembly 515 can be prevented from being lowered due to the temperature rise.

Referring to FIG. 6, as an alternative, in the magnet vertical multistage centrifugal pump according to the second embodiment of the present invention for cooling the magnet assembly, the cooling pipe 70 is disposed outside the outer sleeve 15, the lower end of the cooling pipe 70 is connected to the discharge port 12 of the lower casing 10, and the upper end of the cooling pipe 70 is connected to the cover housing 530 of the magnetic coupling 50, thereby reducing the lower casing 10 A part of the fluid discharged through the discharge port 12 is supplied to the inside of the cover housing 530 through the cooling pipe 70, the fluid is cooled while passing through the cooling pipe 70, and the low-temperature fluid fills the inside of the cover housing 530, and the low-temperature fluid cools the second magnet assembly 525, thereby preventing the temperature of the second magnet assembly 525 from rising and deteriorating magnetic force.

The cooling pipe 70 may be formed of a material such as copper having good thermal conductivity, and includes a radiator such as a heat sink.

The outer rotor 510 has a plurality of exhaust holes 516 formed in the cylindrical holder part 511, and the heat generated by the first magnet assembly 515 and filled in the holder part 511 is discharged to the outside through the exhaust hole 516.

The exhaust hole 516 is disposed above the first magnet assembly 515 in the holder part 511 and is tapered so that its diameter increases from the inner circumferential surface to the outer circumferential surface.

When the magnet vertical multistage centrifugal pump according to the second embodiment of the present invention configured as described above is applied to a boiler or the like and the temperature of the pumping fluid is high, as in the magnet vertical multistage centrifugal pump according to the first embodiment of the present invention, the high temperature pumping fluid flows into the cover housing 530 through the fluid hole 26 of the upper cover 20 (see FIG. Rather, the lowering is prevented, and the cooled low-temperature pumping fluid is supplied to the cover housing 510 through the cooling pipe 70, and the low-temperature fluid cools the second magnet assembly 525, thereby preventing the temperature of the second magnet assembly 525 from rising and lowering the magnetic force.

That is, in the process of discharging the high-temperature fluid through the discharge port 12 of the lower casing 10 in the magnet vertical multistage centrifugal pump according to the second embodiment of the present invention, some of the discharged high-temperature fluid is supplied to the cover housing 530 through the cooling pipe 70. At this time, while the high-temperature fluid passes through the cooling pipe 70, heat is released to the outside through the cooling pipe 70, and the temperature of the fluid is lowered to a low-temperature state, so that the low-temperature fluid is supplied to the cover housing 510 to fill the inside of the cover housing 510. In addition, the low-temperature fluid filled inside the cover housing 510 cools the second magnet assembly 525, so that the temperature of the second magnet assembly 525 rises and the magnetic force decreases. In addition, when the fluid in the cover housing 530 absorbs heat from the second magnet assembly 525 and the temperature of the fluid rises, the heat of the fluid filled in the cover housing 530 is transferred to the low-temperature fluid filled in the cooling pipe 70 in a heat conduction manner, thereby lowering the temperature of the fluid filled in the cover housing 530. In addition, since the heat generated by the first magnet assembly 515 and filled in the holder part 511 is discharged through the exhaust hole 516, the temperature of the first magnet assembly 515 can be prevented from rising, and the magnetic force of the first magnet assembly 515 can be prevented from being lowered due to the temperature rise.

Referring to FIG. 7, as another alternative, in the magnet vertical multistage centrifugal pump according to the third embodiment of the present invention for cooling the magnet assembly, the cooling water supply device 80 is connected to the cover housing 530 of the magnetic coupling 50 through the supply pipe 81, the cooling water of the cooling water supply device 80 is supplied to the cover housing 530 through the supply pipe 81, and the upper end of the discharge pipe 82 in the cover housing 530 Since the lower end of the discharge pipe 82 is connected to the inlet 11 of the lower casing 10, the coolant supplied from the coolant supply device 80 to the cover housing 530 through the supply pipe 81 cools the second magnet assembly 525, and the high-temperature coolant that absorbs heat from the second magnet assembly 525 is discharged through the discharge pipe 82 to the inlet 11 of the lower casing 10.

Valves (not shown) are mounted on the supply pipe 81 and the discharge pipe 82, so that the supply and discharge of cooling water can be controlled by the valves.

The outer rotor 510 has a plurality of exhaust holes 516 formed in the cylindrical holder part 511, and the heat generated by the first magnet assembly 515 and filled in the holder part 511 is discharged to the outside through the exhaust hole 516.

The exhaust hole 516 is disposed above the first magnet assembly 515 in the holder part 511 and is tapered so that its diameter increases from the inner circumferential surface to the outer circumferential surface.

The magnet vertical multistage centrifugal pump according to the third embodiment of the present invention for cooling the magnet assembly as described above, like the magnet vertical multistage centrifugal pump according to the second embodiment of the present invention, is applied when the pump is used in a boiler or the like for pumping high-temperature fluid, and has the advantage of sufficiently cooling the second magnet assembly 525 so that the magnetic force of the second magnet assembly 525 does not decrease regardless of the temperature of the pumped fluid.

As described above, the present invention has been described by specific details such as specific components and limited embodiments and drawings, but this is only provided to help a more general understanding of the present invention, the present invention is not limited to the above embodiments, and those skilled in the art can make various modifications and variations from these descriptions.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims described later, but also all modifications equivalent or equivalent to these claims belong to the scope of the present invention.

10: lower casing 11: inlet
12: discharge port 15: outer sleeve
20: upper cover 30: stage
40: motor 50: magnetic coupling

Claims (10)

delete The lower casing 10 in which the suction port 11 and the discharge port 12 are formed, the outer sleeve 15 standing on the lower casing 10, the upper cover 20 mounted on the upper end of the outer sleeve 15, the stage 30 stacked in multiple stages on the lower casing 10 and including the impeller 31 and the diffuser 32 therein, the stage 30 stacked in multiple stages, and the outer sleeve 15 The outer rotor 510 is mounted on the passage gap 17 formed between, the shaft 35 that passes through the center of the stacked stages 30 and is coupled to the impeller 31 of the stage 30, the motor 40 disposed on the top of the upper cover 20, and the drive shaft 41 of the motor 40, and the inner rotor 520 is mounted on top of the shaft 35, so that the outer rotor 510 1 magnet assembly 515 and the second magnet assembly 525 of the inner rotor 520 are disposed to face each other, so that the power of the motor 40 is transmitted to the shaft 35 by magnetic force. Includes a magnetic coupling 50,
The magnetic coupling 50 includes an outer rotor 510 connected to the driving shaft 41 of the motor 40, a first magnet assembly 515 mounted on an inner circumferential surface of the outer rotor 510, an inner rotor 520 mounted on an upper end of the shaft 35, a second magnet assembly 525 mounted on an outer circumferential surface of the inner rotor 520, and the outer rotor 520, A non-magnetic cover housing 530 disposed between the rotor 510 and the inner rotor 520, a stator bushing 65 mounted on the upper cover 20 and disposed around the shaft 35, and a rotor bushing 60 mounted on the lower surface of the inner rotor 520 and rotatably seated on the upper surface of the stator bushing 65,
In the outer rotor 510, a hollow part 512 is formed in the cylindrical holder part 511, a shaft connection part 513 is formed at the upper end of the holder part 511, and a shaft hole 514 is formed in the shaft connection part 513. ,
The inner rotor 520 is formed in a cylindrical shape, a soccer hole 521 is formed in the center, the shaft 35 is fitted into the soccer hole 521, a pocket 522 is formed in the center of the upper surface, the upper fastening portion 36 of the shaft 35 protrudes into the pocket 522 through the soccer hole 521, and the nut 37 is fastened to the upper fastening portion 36 of the shaft 35 protruding into the pocket 522. And, the second magnet assembly 525 is mounted on the outer circumferential surface, and the rotor bushing 60 is coupled to the lower surface by bolts 61,
In the first magnet assembly 515 and the second magnet assembly 525, a plurality of permanent magnets 517 and 527 are arranged alternately with N poles and S poles in a ring shape, the S pole of the permanent magnet 527 is disposed to correspond to the N of the permanent magnet 517, and the N pole of the permanent magnet 527 is disposed to correspond to the S of the permanent magnet 517,
The cover housing 530 is formed in a cylindrical cup shape in which the main body 531 is inverted, a lower opening 532 is formed at the lower portion of the main body 531, a supporting portion 533 is formed around the lower end of the main body 531, and a bolt 535 is fastened to the upper cover 20 through a pressing member 534, so that the pressing member 534 presses the supporting portion 533, thereby pressing the supporting portion ( 533) the upper cover 20 is compressed,
The outer rotor 510 has a plurality of exhaust holes 516 formed on the circumferential surface of the cylindrical holder part 511, and the heat generated by the first magnet assembly 515 and filled in the holder part 511 is discharged to the outside through the exhaust hole 516. Magnet vertical multistage centrifugal pump, characterized in that.
delete According to claim 2,
The upper cover 20 includes a cylindrical portion 21 seated on the upper end of the outer sleeve 15 and a disk portion 22 integrally formed with the cylindrical portion 21 and disposed inside the cylindrical portion 21, a center hole 23 through which the shaft 35 passes is formed at the center of the disk portion 22, a first seating portion 24 is formed around the center hole 23, and a first seating portion 24 is formed around the center hole 23. The stator bushing 65 is disposed on the portion 24, the rotor bushing 60 coupled to the lower surface of the inner rotor 520 is seated on the upper surface of the stator bushing 65 to be relatively rotatable, and the second seating portion 25 is formed around the outer circumference of the first seating portion 24, and the support portion 533 of the cover housing 530 and the pressing member ( 534) is a magnet vertical multistage centrifugal pump, characterized in that disposed.
According to claim 4,
The rotor bushing 60 and the stator bushing 65 are made of silicon carbide (silicon carbide) material with high wear resistance, and the wear resistance of the stator bushing 65 is higher than that of the rotor bushing 60. Magnet vertical multistage centrifugal pump, characterized in that higher.
According to claim 2,
The rotor bushing 60 coupled to the lower surface of the inner rotor 520 is seated on the stator bushing 65 disposed on the first seating part 24 of the upper cover 20, the second magnet assembly 525 is mounted on the outer circumferential surface of the inner rotor 520, and the upper fastening part 36 of the shaft 35 is inserted into the pocket 522 through the hole 521 of the inner rotor 520. As the nut 37 is fastened to the upper fastening portion 36 of the shaft 35 protruding into the pocket 522, the shaft 35 is supported by the inner rotor 520, the inner rotor 520 is rotatably supported by the upper cover 20 through the rotor bushing 60 and the stator bushing 65, and the cover housing 530 covers the inner rotor 520. The support portion 533 and the pressing member 534 of the ) are mounted on the second seating portion 25 of the upper cover 20, the shaft connection portion 513 of the outer rotor 510 is connected to the drive shaft 41 of the motor 40, and the holder portion 511 of the outer rotor 510 surrounds the cover housing 530, so that the first magnet mounted on the inner circumferential surface of the holder portion 511 Magnet vertical multistage centrifugal pump, characterized in that the assembly 515 is disposed to face the second magnet assembly 525 mounted on the outer circumferential surface of the inner rotor 520 with the cover housing 530 interposed therebetween.
According to claim 2,
A fluid hole 26 is formed in the upper cover 20, fluid flows into the cover housing 530 through the fluid hole 26, and a gap 540 is formed between the main body 531 of the cover housing 530 and the second magnet assembly 525 of the inner rotor 520, so that the fluid flowing into the cover housing 530 flows into the pocket 5 of the inner rotor 520 through the gap 540. 22) as well as being supplied to the inside of the cover housing 530, characterized in that the magnet vertical multi-stage centrifugal pump.
delete According to claim 2,
The cooling pipe 70 is disposed outside the outer sleeve 15, the lower end of the cooling pipe 70 is connected to the outlet 12 of the lower casing 10, and the upper end of the cooling pipe 70 is connected to the cover housing 530 of the magnetic coupling 50, so that a part of the fluid discharged through the outlet 12 of the lower casing 10 is supplied to the inside of the cover housing 530 through the cooling pipe 70, The liquid is cooled in the process of passing through the cooling pipe 70, and the low-temperature fluid fills the inside of the cover housing 530, and the low-temperature fluid cools the second magnet assembly 525, thereby preventing the temperature of the second magnet assembly 525 from rising and deteriorating magnetic force.
According to claim 2,
The cooling water supply device 80 is connected to the cover housing 530 of the magnetic coupling 50 through the supply pipe 81, the cooling water of the cooling water supply device 80 is supplied to the cover housing 530 through the supply pipe 81, the upper end of the discharge pipe 82 is connected to the cover housing 530, and the lower end of the discharge pipe 82 is connected to the inlet 11 of the lower casing 10, so that the cooling water supply device 80 The cooling water supplied to the cover housing 530 through the supply pipe 81 cools the second magnet assembly 525, and the high-temperature cooling water that absorbs the heat of the second magnet assembly 525 is discharged through the discharge pipe 82. Magnet vertical multistage centrifugal pump characterized in that it is discharged to the inlet 11 of the lower casing 10.

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