KR101236884B1 - rising type underwater motor pump using a magnetic field - Google Patents

Abstract

The present invention relates to a magnetically levitated submersible motor pump, wherein the permanent magnetic rotor (31) is installed as a shaft in the rotor insertion cylinder (12), and the rotating magnetic part (30) drawn out to the motor housing (10). Floating stator magnets are mounted on both ends of the rotary shaft 36 of the rotary shaft 36, and fluid flowing into (impeded into) the impeller chambers 21 and 61 is inserted into the rotor insertion tube 12 and fixed thereto. A water film phenomenon occurs between the 32 and 34 and the rotating permanent magnet rotor 31, and the magnetic field is injured between the permanent magnet rotor 31 and the floating stator magnets 32 and 34. By removing the friction by lubricating the water film formed between the permanent magnet rotor 31 and the floating stator magnets (32, 34) and to maintain the concentricity of the permanent magnet rotor (31) by the magnetic field It eliminates vibration, water cooling effect by inflowing fluid (water) and friction and vibration due to magnetic field injury. By the removal of the pump performance can be obtained in high efficiency.

Description

Rising type underwater motor pump using a magnetic field}

It relates to a magnetic field floating submersible motor pump according to the present invention, in particular a permanent magnet rotor installed in the rotor shaft as a shaft, and protrudes to the outside of the rotor insertion tube and the motor housing cover formed in the center of the motor housing The upper and lower impellers are mounted on the upper and lower ends of the rotating shaft, respectively, and the fluid flowing into the upper impeller cover and the lower impeller chamber cover flows into the rotor insertion tube, where the upper and lower floating stator magnets and the rotating permanent magnets are fixed. A magnetically levitated submersible motor pump that prevents frictional heat and frictional noise of the motor by forming water film phenomenon and magnetic field injury between the rotor and the friction of the rotating shaft without friction with the permanent magnet rotor. will be.

In general, the submersible motor pump is used for pumping or draining the entire pump in water (fluid), such as pumping water (fluid), supplying water or drugs, conveying the liquid water to other processes, etc. It is used in various fields.

These conventional submersible motor pumps are formed so that the motor unit and the pump unit can be integrally formed or separated to be coupled to each other so that the impeller of the pump unit rotates and sucks water (fluid) by the operation of the motor unit. .

However, they are provided with a rotor (rotor) and a stator (magnetic core) of the motor part together in the motor casing, and the motor part and the pump part are sealed or separated from each other, so that the water pumped from the pump part flows into the motor part. It becomes impossible.

Therefore, the motor part has to apply lubricant between the rotor (rotor) and the stator (magnetic core), and when the motor part is repaired, there is a problem that the lubricant leaks to the outside and contaminates the rotor (rotor) by the bearing only. Since the concentricity is supported, the bearing may be worn for a long time, and thus the concentricity may not be achieved accurately, as well as vibration and noise may occur.

In addition, the heat generated by the operation of the motor unit is transferred to the motor casing and indirectly cooled by air and water (fluid) in contact with the outside (outer surface) of the motor casing, thereby decreasing the cooling efficiency. Increasing the temperature of the motor unit has a problem in that the performance is lowered to lower the efficiency of the pump.

In addition, since the conventional submersible motor pump is provided with one pump unit in the motor unit, there is a simplicity that cannot be utilized for different purposes using one pump.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a magnetic field floating submersible motor that can be obtained and used in water and does not need to apply lubricant between the rotor and the stator. .

It is another object of the present invention to attach a floating magnet to both ends of the rotor so that the rotor rotates in a floating state without contacting the motor housing so that there is no friction, thus making the magnetic field floating underwater motor highly efficient without noise and vibration. To provide.

Another object of the present invention is to install the rotor in the rotor insertion tube formed in the center of the motor housing to separate from the stator and the fluid flows into the rotor insertion tube lubrication effect by the water film phenomenon by the introduced fluid To provide a magnetic field floating submersible motor that can achieve the cooling effect.

In order to achieve the above object, the magnetic field floating underwater motor according to the present invention has an upper impeller seal in which an upper part thereof is sealed and an lower part is opened, and an upper impeller is installed on an upper surface thereof, and communicates with the upper impeller seal. A motor housing having a rotor insertion tube formed to rotate by inserting an electromagnetic field portion; An upper impeller chamber cover covering the upper impeller chamber and having an inlet through which a fluid pumped in accordance with the rotation of the upper impeller; A rotating magnetic part installed in the rotor insertion tube of the motor housing and rotating; A stator magnetic part fixed in the motor housing and generating a magnetic field in the rotating magnetic part; A motor housing cover covering a lower opening of the motor housing and having a rotor cylindrical insertion portion into which the rotor insertion tube is inserted and having a lower impeller seal at a bottom thereof; The lower impeller chamber cover includes a lower impeller chamber covering the lower impeller chamber of the motor housing cover and having an inlet through which water pumped in accordance with the rotation of the lower impeller.

According to an embodiment of the present invention, the magnetic field portion is inserted into the rotor insertion tube of the wintong case, and the N and S poles are symmetrically formed by a vertical plane passing through the center of the rotating shaft, thereby generating a magnetic field. A permanent magnet rotor rotating by; A rotating shaft fitted into a distribution hole formed at the center of the permanent magnet rotor and fixed by a bushing; An upper floating stator magnet having a distribution hole fitted to the rotating shaft at a center thereof and fitted to an upper portion of the rotor insertion tube and having a conical inner space; An upper floating rotating magnet inserted into the rotary shaft through the distribution hole and fixed by a bushing and inserted into a conical shape of the upper floating stator magnet and having a magnet polarity opposite to that of the upper floating stator magnet; A lower floating stator magnet having a distribution hole fitted to the rotating shaft at a center thereof, the lower floating stator magnet being fixed to the rotor insertion tube and having a conical inner space; It is inserted into the rotating shaft through the distribution hole is fixed by the bushing and inserted into the inner space of the conical shape of the lower floating stator magnet and consists of a lower floating rotor magnet having a magnet polarity opposite to the polarity of the lower floating stator magnet It is done.

According to one embodiment of the present invention, the fixed magnetic field is cylindrical and its inside is formed in a hexagonal cylinder shape, and is fitted into and fixed to an inner circumferential surface of the motor housing; Six cores fitted into six fixing grooves formed on an inner circumferential surface of the hexagonal column of the cylindrical body; It is characterized by consisting of the six coil bobbin fitted to the six core and the coil wound.

According to an embodiment of the present invention, the upper and lower floating fixed magnets are in the shape of a cylinder in which a conical space is formed at the center of the inner surface thereof to smooth the injuries, and the upper and lower floating rotating magnets are formed in a conical shape. , Can be inserted into each of the conical space of the lower floating stator magnets, can be matched with each other, the repulsive force is applied to each other by the polarity of the magnet to rise, and the magnetic field in the central portion is characterized by being configured to be small.

According to the present invention, the water film formed between the floating fixed magnet and the permanent magnet rotor is lubricated, and between the magnetic field and the permanent magnet rotor by the floating staging magnet installed inside the rotor insertion tube. By forming a magnetic field and floating, it can rotate while maintaining the concentricity of the rotor (permanent magnet rotor), so that a cooling effect can also be obtained by the fluid (water) circulating at the same time without generating vibration. In addition, the high pressure pumping is possible due to the organic action of the impeller of the pump.

1 is an exploded perspective view showing the configuration of the magnetic field floating submersible motor pump according to the present invention,
2 is a perspective view showing the inside of the motor housing according to the present invention;
3A is an exploded perspective view of a rotating magnetic field unit according to the present invention;
3B is a cross-sectional view of the rotating magnetic field cut by the vertical plane passing through the center of the rotating shaft according to the present invention;
Figure 3c is a magnetic field generated in the upper floating rotor and upper floating stationary magnet according to the present invention,
Figure 3d is a magnetic field generated in the lower floating rotary magnet and the lower floating stationary magnet according to the present invention,
4 is an exploded perspective view of a fixed magnetic field unit according to the present invention;
5A is a state in which the fixed magnetic field unit according to the present invention is assembled,
5b is a cross-sectional view horizontally cut along the line A-A 'of the fixed magnetic field according to the present invention,
5A and 5B illustrate pulses output from an encoder switch in a level jump mode according to the present invention;
6 is a cross-sectional view of the magnetic field floating underwater motor according to the present invention cut in a vertical plane passing through the center thereof.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing the configuration of the magnetic field floating submersible motor pump according to the present invention.

In the magnetically levitated submersible motor pump according to the present invention, the upper part is closed and the lower part is open, and the upper impeller 25 is installed by being protruded from the upper surface and pumped according to the rotation of the upper impeller 25. An upper impeller chamber 11 having a discharge port 13 for discharging water, and the upper impeller 25 is fitted in one end, and communicates with the upper impeller chamber 11 and the rotor magnetic field of the brushless motor ( A motor housing (10) having a rotor insertion tube (12) inserted and formed to rotate and having a stator field portion (40) of the brushless motor fixed to an inner circumferential surface thereof; A lower impeller chamber cover 20 covering the upper impeller chamber 11 and having an inlet 21 through which water pumped in accordance with rotation of the upper impeller 25 is introduced; A rotor magnetic part 30 inserted into the rotor insertion tube 12 of the motor housing 10 and rotating; A stator field part 40 fixed inside the motor housing 10 and constituting a stator of the brushless motor; Its upper portion is open to cover the lower opening portion of the motor housing 10 and has a rotor cylindrical insertion portion 62 into which the rotor insertion tube 12 is fitted, and the bottom thereof extends downward to protrude. A motor housing cover (60) having a lower impeller seal (61) on which a lower impeller (75) is installed and an outlet (63) for discharging water pumped according to the rotation of the lower impeller (75); The lower impeller chamber cover 70 includes a lower portion of the motor housing cover 60 and an inlet 71 through which water pumped in accordance with the rotation of the lower impeller 75 flows.

2 is a perspective view showing the inside of the motor housing according to the present invention.

The motor housing 10 according to the present invention includes a cylindrical case 14 whose upper surface is closed and the lower surface is open; An upper impeller seal 11 having a cylindrical shape protruding from the upper surface of the cylindrical case 14 and having an upper impeller 25 installed therein and having an outlet 13 for discharging water pumped according to the rotation of the upper impeller 25. Wow; A rotor insertion tube 12 protruding downward from an inner center of an upper surface of the cylindrical case 14; It consists of a rotating shaft hole 15 formed in the bottom surface of the rotor insertion cylinder 12 so that the rotating shaft 36 of the rotating magnetic field portion 30 is inserted.

The cylindrical case 14 may be manufactured by a die casting or plastic molding device, and a cylindrical rotor insertion tube 12 is formed at an inner center thereof to protrude downward to insert the rotating magnetic field portion 30 from the outside. .

Therefore, the inside of the rotor insertion cylinder 12 and the cylindrical case 14 is blocked by not communicating with each other. That is, water may pass through the rotor insertion cylinder 12, but the rotor insertion cylinder 12 is inserted into the rotor cylindrical insertion portion 62 formed at the inner center of the motor housing cover 60 to be sealed to the rotor insertion cylinder. Water passing through (12) (water pumped by the upper impeller 25) is sealed so as not to penetrate into the inside of the cylindrical case 14.

At this time, the lower end of the rotating shaft 36 of the rotor magnetic field part 30 protrudes through the rotating shaft hole 15 formed in the bottom surface of the rotor insertion tube 12 to the lower impeller chamber 61 formed in the motor housing cover 60. It is fastened with the lower impeller 75 is installed.

The inside of the cylindrical case 14 is formed with a cavity to insert the fixed magnetic field portion 40, the inside of the closed upper surface of the cylindrical case 14 to fix the fixed magnetic field portion 40 with a screw (45a) A plurality of screw holes 16a are formed. A plurality of screw holes 45 corresponding to the screw holes 16a of the cylindrical case 14 are formed in the fixed magnetic field part 40 and are fixed by being fastened to the screw holes 16a by the screws 45a.

3 is an exploded perspective view of the rotating magnetic field unit according to the present invention.

The rotating magnetic field part 30 according to the present invention is inserted into the rotor insertion tube 12 of the win barrel case 14 and is fixed by forming an N pole and an S pole symmetrically by a vertical plane passing through the center of the rotation shaft 36. A permanent magnet rotor 31 rotating by the magnetic field generated by the magnetic field part 40; A rotating shaft 36 inserted into a distribution hole 31a formed at the center of the permanent magnet rotor 31 and fixed by a bushing 31b; An upper floating stator magnet 32 having a distribution hole 32a fitted to the rotation shaft 36 at a center thereof and fitted to an upper portion of the rotor insertion tube 12 and having a conical inner space; It is inserted into the rotary shaft 36 through the flow hole (33a) and is fixed by the bushing 37 and inserted into the inner space of the conical shape of the upper floating stator magnet 32 and the polarity of the upper floating stator magnet (32) An upper floating rotor magnet 33 having opposite magnet polarity; A lower floating stator magnet 34 having a distribution hole 34a fitted to the rotation shaft 36 at a center thereof, fixed to the rotor insertion tube 12 at a lower portion thereof, and having a conical inner space; It is inserted into the rotary shaft 36 through the distribution hole (35a) and is fixed by the bushing 38 and inserted into the inner space of the conical shape of the lower floating stator magnet 34 and the polarity of the lower floating stator magnet (34) It consists of a lower floating rotor magnet 35 having the opposite magnet polarity.

The permanent magnet rotor 31 has a cylindrical shape and is rotated by a magnetic field generated by a fixed magnetic field part 40 which is inserted into the rotor insertion cylinder 12 of the win barrel case 14 and installed inside the win cylinder case 14. It will rotate about (36).

3B is a cross-sectional view of the rotating magnetic field cut in the vertical plane passing through the center of the rotating shaft according to the present invention.

As shown, the permanent magnet rotor 31 is symmetrical with respect to the vertical plane passing through the center of the rotation axis 36 and the north pole and the south pole is formed by the magnetic field generated in the fixed magnetic field portion 40.

The upper floating stator magnet 32 has a distribution hole 32a at the center thereof and is fitted to the rotation shaft 36 through the distribution hole 32a and then fixed to the upper portion of the rotor insertion tube 12. The inner space of the upper floating stator magnet 32 is conical to become thicker toward the top and thinner toward the bottom.

Since the upper floating rotary magnet 33 has a conical shape that matches the conical shape of the inner space of the upper floating stator magnet 32, the upper floating rotary magnet 33 is placed in the inner space of the upper floating stator magnet 32. Can be inserted and mated.

However, since the upper floating rotor magnet 33 has the opposite polarity with the upper floating stationary magnet 32 as shown in FIG. 3C, pushing forces are applied to each other to maintain a constant distance without contacting each other.

Similarly, the lower floating stator magnet 34 has a distribution hole 34a into which the rotary shaft 36 is fitted at the center thereof, and is fitted into the rotary shaft 36 and then fixed in contact with the bottom bottom of the rotor insertion tube 12. The inner space of the lower floating stator magnet 34 is formed in a conical shape so as to become narrower toward the bottom and wider toward the top. That is, the same shape as the upper floating stator magnet 32, but is reversed in the opposite direction is fixed to the bottom bottom of the rotor insertion cylinder (12).

The lower floating rotary magnet 35 is conical to match the conical shape of the inner space of the lower floating stator 34, and may be inserted into and matched with the inner space of the lower floating stator 34.

However, since the lower floating rotor magnet 35 is opposite in polarity to the lower floating stator magnet 34 as shown in FIG. 3D, the lower floating rotor magnet 35 is assembled with the lower floating stator magnet 34 to rotate the rotor. The force pushing each other in the state inserted into the insertion tube 12 is not in contact with each other to maintain a constant interval to be in an injured state.

4 is an exploded perspective view of the stationary magnetic field unit according to the present invention.

The fixed magnetic field part 40 according to the present invention has a cylindrical shape, the inside of which is formed in a hexagonal cylinder shape, and is fitted into and fixed to an inner circumferential surface of the motor housing 10; Six cores 42a-42f fitted into six fixing grooves 44a-44f formed on the inner circumferential surface of the hexagonal column of the cylindrical body 41; It consists of six coil bobbins 43a-43f fitted to the six cores 42a-42f and wound with a coil.

The cylindrical body 41 has a cylindrical outer shape and an inner space thereof is formed in a hexagonal column shape, and six fixing grooves 44a-44f are formed to fit the cores 42 on six sides of the hexagonal column.

The core 42 is composed of a cylindrical body 421 fitted into the fixing groove 44 and a core body portion 422 extending radially integrally with the cylindrical body 421 and formed into a rectangular parallelepiped. In addition, the opposite side 423 of the surface attached to the cylindrical body 421 of the core body portion 422 is formed to be concave round so as to have a constant interval when the cylindrical rotor insertion cylinder 12 is inserted. .

5A shows a state in which the fixed magnetic field unit according to the present invention is assembled, and in FIG. 5B, a cross-sectional view in which the fixed magnetic field unit according to the present invention is cut along the line AA ′ is illustrated.

When the coil bobbin 43 is inserted into the core 42 and a current flows through the coil wound around the coil bobbin 43, the stator field part in the cylindrical body 421 as shown in FIG. 5B according to the direction of the current flowing through the coil. A magnetic field towards the center of 40 occurs or a magnetic field in the opposite direction occurs.

The magnetic field generated by the six cores 42a-42f acts on the permanent magnet rotor 31 of the rotating magnetic field part 30 fitted to the inner center of the fixed magnetic field part 40 to permanent magnet rotor 31. Rotate

6 is a cross-sectional view of the magnetic field floating underwater motor according to the present invention cut into a vertical plane passing through the center thereof.

In the magnetic field floating underwater motor 100 according to the present invention, when a current flows in a coil wound on the coil bobbin 43, a magnetic field is generated as shown in FIG. 5B, and thus the permanent magnet rotor 31 of the rotating magnetic field part 30. To rotate the permanent magnet rotor 31.

Since the rotating shaft 36 is fixed to the permanent magnet rotor 31 by the bushing 31b, the rotating shaft 36 also rotates together. In addition, the upper impeller 25 and the lower impeller 75 are attached to both ends of the rotating shaft 36 to rotate together with the rotation of the permanent magnet rotor 31 so that the upper impeller chamber 11 and the lower impeller chamber 61 are rotated together. Discharge the water in the outlet (13, 63) to make the upper impeller chamber 11 and the lower impeller chamber 61 to the negative pressure.

The upper impeller chamber 11 and the lower impeller chamber 61 become negative pressure to suck the fluid (eg, water) from the outside through the inlets 21 and 71. The fluid sucked from the inlets 21, 71 is thus fed to the next process via conduits connected to the outlets 13, 63.

As described above, when water is pumped out by the rotation of the impeller 25, a part of the fluid sucked into the upper impeller chamber 11 is formed of the floating stator magnets 32 and 34 mounted on the rotor insertion tube 12. The fluid flowing into the rotor insertion cylinder 12 through the distribution holes 32a and 34a, and the fluid flowing into the rotor insertion cylinder 12, flows through the distribution hole of the lower floating fixed magnet 34 mounted below. It can be deeply introduced into the motor housing cover 60 through the rotation shaft hole 15 formed in the bottom surface of the rotor insertion cylinder 12 through 34a.

On the contrary, a part of the fluid sucked into the lower impeller chamber 61 of the motor housing cover 60 is transferred to the rotor insertion cylinder 12 through the rotation shaft hole 15 formed in the bottom surface of the rotor insertion cylinder 12. Is introduced into the upper impeller chamber 11 through the distribution holes (32a, 34a) of the floating fixed magnets (32, 34).

The fluid flowing into the rotor insertion cylinder 12 includes the floating rotor magnets 33 and 35 fixed to the rotating shaft 36 and the floating stator magnets 32 and 34 fixed inside the rotor insertion cylinder 12. It penetrates through and forms a water film, penetrates between an inner circumference of the rotor insertion tube 12 and an outer circumference of the permanent magnet rotor 31 to form a water film, and at the same time, an injury occurs by a magnetic field.

In this way, the water film formed between the permanent magnet rotor 31 and the floating magnet 33 fixed to the rotating shaft 36, the inner circumference of the rotor insertion cylinder 12 and the permanent magnet rotor 31 of the Injuries due to the water film and the magnetic field formed between the outer circumferences are lubricated so that the permanent magnet rotor 31 can rotate smoothly, and the center of the permanent magnet rotor 31 can be rotated on an accurate center line. Will be maintained.

The water flowing into the rotor insertion cylinder 12 is circulated by the operation of the impellers 25 and 75 while cooling the heat generated by the coil bobbin 43 and the permanent magnet rotor 31 (fluid). If water is water) so that the internal cooling effect of the rotor insertion cylinder 12 can be greatly improved.

10: motor housing 11, 61: upper and lower impeller chamber
12: rotor insertion container 13, 63: outlet
14: cylinder case 15: shaft hole
20: upper impeller chamber cover 21, 71: inlet
25: upper impeller 30: rotating magnetic field
31: permanent magnet rotor 31b, 37, 38: bushing
32, 34: Upper and lower floating stator magnet 33, 35: Upper and lower floating stator magnet 36: Rotating shaft 40: Fixed magnetic field
41: cylindrical body 42: core
43: coil bobbin 44: fixing groove
45: screw hole 45a: screw
60: motor housing cover 62: rotor cylindrical insert
70: lower impeller chamber cover 100: magnetic field floating submersible motor pump

Claims (4)

Its upper part is sealed and its lower part is open and has an upper impeller seal 11 on which an upper impeller 25 is installed, and communicates with the upper impeller seal 11 and a rotor magnetic part 30 is inserted therein. A motor housing 10 having a rotor insertion tube 12 formed to rotate;
An upper impeller chamber cover (20) covering the upper impeller chamber (11) and having an inlet (21) through which the fluid pumped in accordance with the rotation of the upper impeller (25);
A rotor magnetic part 30 inserted into the rotor insertion tube 12 of the motor housing 10 and rotating;
A stator magnetic part 40 fixed inside the motor housing 10 and generating a magnetic field in the rotating magnetic part;
Lower impeller seal which covers the lower opening of the motor housing 10 and has a rotor cylindrical insert 62 into which the rotor insert 12 is fitted, and a lower impeller 75 is installed at the bottom thereof. A motor housing cover 60 having a 61;
It consists of a lower impeller chamber cover 70 which covers the lower impeller chamber 61 of the motor housing cover 60 and has an inlet 71 through which water pumped in accordance with the rotation of the lower impeller 75 flows. Magnetically levitated submersible motor pump. According to claim 1, The magnetic field portion 30 is inserted into the rotor insertion tube 12 of the winch case 14 and the N pole and the S pole symmetrically by a vertical plane passing through the center of the rotation axis 36 A permanent magnet rotor 31 formed to rotate by a magnetic field generated by the fixed magnetic field part 40; A rotating shaft 36 inserted into a distribution hole 31a formed at the center of the permanent magnet rotor 31 and fixed by a bushing 31b; An upper floating stator magnet 32 having a distribution hole 32a fitted to the rotation shaft 36 at a center thereof and fitted to an upper portion of the rotor insertion tube 12 and having a conical inner space; It is inserted into the rotary shaft 36 through the flow hole (33a) and is fixed by the bushing 37 and inserted into the inner space of the conical shape of the upper floating stator magnet 32 and the polarity of the upper floating stator magnet (32) An upper floating rotor magnet 33 having opposite magnet polarity; A lower floating stator magnet 34 having a distribution hole 34a fitted to the rotation shaft 36 at a center thereof, fixed to the rotor insertion tube 12 at a lower portion thereof, and having a conical inner space; It is inserted into the rotary shaft 36 through the distribution hole (35a) and is fixed by the bushing 38 and inserted into the inner space of the conical shape of the lower floating stator magnet 34 and the polarity of the lower floating stator magnet (34) Magnetically levitated submersible motor pump, characterized in that consisting of the lower floating rotary magnet (35) having the opposite polarity of the magnet. According to claim 1, wherein the fixed magnetic field portion 40 is cylindrical and its inside is formed in a hexagonal cylinder shape, the cylindrical body 41 is fitted to the inner circumferential surface of the motor housing 10 and fixed; Six cores 42a-42f fitted into six fixing grooves 44a-44f formed on the inner circumferential surface of the hexagonal column of the cylindrical body 41; Magnetically floating submersible motor pump, characterized in that consisting of the six coils (42a-42f) and the six coil bobbin (43a-43f) is wound coil. The upper and lower floating stator magnets 32 and 34 have a cylindrical shape in which a conical space is formed at the center of the inner surface of the upper and lower floating stator magnets 32 and 35, and the upper and lower floating rotor magnets 33 and 35. ) Is formed in a conical shape and inserted into the conical spaces of the upper and lower floating magnets 32 and 34, respectively, can be matched with each other, the magnetic field injury, characterized in that the repulsive force acts on each other by the polarity of the magnet Type submersible motor pump.

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