KR101541777B1 - Submerged motor having improved cooling efficiency - Google Patents

Abstract

The present invention relates to an underwater motor used in an underwater pump, which can prevent a dewing phenomenon caused by a temperature difference in a coil of a stator, and can uniformly cool the rotor and the stator, To an underwater motor having an improved cooling efficiency that can prolong the service life of the motor.

Description

[0001] The present invention relates to a submerged motor having improved cooling efficiency,

The present invention relates to an underwater motor used in an underwater pump, which can prevent a dewing phenomenon caused by a temperature difference in a coil of a stator, and can uniformly cool the rotor and the stator, To an underwater motor having an improved cooling efficiency that can prolong the service life of the motor.

Generally, submersible motors are used separately or in combination as a submersible pump, and submersible pumps are used in water to be used for water supply or pumping.

At this time, since the underwater motor is used in water, it is made to have a waterproof function, and in particular, the stator on which the coil is wound is formed to be sealed from water.

However, since the stator and the rotor of the underwater motor generate heat during operation, the stator is coupled to the inside of the case to transmit heat to the water outside the case, Thereby causing condensation of moisture in the stator. As a result, shorting may occur due to condensation of moisture around the stator, and the efficiency of the motor is lowered due to overheating of the stator and the life is shortened.

A related art related to this is disclosed in Korean Patent Laid-Open Publication No. 10-2010-0030537 entitled " Submersible Motor Pump ".

KR 10-2010-0030537 A (2010.03.18.)

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide an underwater motor in which a rotor and a stator of an underwater motor are uniformly cooled and cooling efficiency is improved, And which has an improved cooling efficiency.

In order to achieve the above object, the underwater motor having improved cooling efficiency of the present invention comprises: an outer housing (100) having an inner hollow and open at both sides; A stator 200 formed on the inner side of the outer housing 100 and wound with a coil; A rotor 300 disposed inside the stator 200; A shaft 400 coupled to the center of the rotor 300 and having a cooling passage 410 formed along the longitudinal direction thereof to form a helical groove 411 or a helical baffle in the cooling passage 410; An upper casing 500 and a lower casing 600 coupled to both sides of the outer housing 100 so as to be hermetically sealed on the outside and coupled to both sides of the shaft 400 so as to be rotatable; And an inner housing 700 spaced between the stator 200 and the rotor 300 and hermetically coupled to both the upper casing 500 and the lower casing 600; And a control unit.

The upper casing 500 and the lower casing 600 are formed with steps 530 and 630 so as to be caught by the outer housing 100 and are inserted into the outer housing 100, The first insertion portions 510 and 610 are formed so as to protrude from the second insertion portions 520 and 620 and to be inserted into the inner housing 700.

Both sides of the shaft 400 are coupled to the upper casing 500 and the lower casing 600 by bushes 550 and 650 or bearings so as to be rotatable, and between the shaft 400 and the upper casing 500, And the fluid is formed between the lower casing 400 and the lower casing 600.

A wire outlet hole 561 is formed through the upper casing 500 so that the wires 210 connected to the coil of the stator 200 are drawn out and a wire 210 are inserted into the sealing member 580 such that the wires 210 are coupled to penetrate the cover 570 and the cover 570 is coupled to the upper casing 500 so that the sealing member 580 is in close contact .

In addition, the upper casing 500 is characterized in that the cover 560 is formed concavely with the cover 570 inserted therein.

In addition, the cover 570 is formed with a sealing member recess groove 571 concaved to receive the sealing member 580 therein.

INDUSTRIAL APPLICABILITY The submersible motor having improved cooling efficiency of the present invention has an advantage that the rotor and the stator of the submersible motor are uniformly cooled and the cooling efficiency is improved to prevent the performance of the submersible motor from deteriorating and the lifetime of the submersible motor can be improved .

1 and 2 are an exploded cross-sectional view and an assembled cross-sectional view of an underwater motor with improved cooling efficiency according to an embodiment of the present invention.
3 is a partially enlarged view of the cooling flow path of the shaft and the flow of water into the interior of the inner housing according to the present invention.
4 and 5 are a partially enlarged view and an exploded perspective view showing a sealing structure of a wire connected to a coil according to the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an underwater motor having improved cooling efficiency according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are an exploded cross-sectional view and an assembled cross-sectional view of an underwater motor having improved cooling efficiency according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view illustrating a cooling channel of a shaft and a flow of water into the interior of the inner housing according to the present invention Fig.

As shown in the drawings, an underwater motor 1000 having improved cooling efficiency according to the present invention includes: an outer housing 100 having an inner hollow and open on both sides; A stator 200 formed on the inner side of the outer housing 100 and wound with a coil; A rotor 300 disposed inside the stator 200; A shaft 400 coupled to the center of the rotor 300 and having a cooling passage 410 formed along the longitudinal direction thereof to form a helical groove 411 or a helical baffle in the cooling passage 410; An upper casing 500 and a lower casing 600 coupled to both sides of the outer housing 100 so as to be hermetically sealed on the outside and coupled to both sides of the shaft 400 so as to be rotatable; And an inner housing 700 spaced between the stator 200 and the rotor 300 and hermetically coupled to both the upper casing 500 and the lower casing 600; .

First, the outer housing 100 is formed in a cylindrical shape, and the inner portion of the outer housing 100 is hollow and both ends thereof are opened.

The stator 200 is coupled and fixed to the inside of the outer housing 100, and coils are wound. At this time, the inside of the stator 200 is formed hollow.

The rotor 300 is provided on the hollow inside of the stator 200 and the stator 200 and the rotor 300 are spaced apart from each other with a predetermined clearance so that the rotor 300 can be rotated.

The shaft 400 is coupled to the center of the rotor 300 and rotates together with the rotor 300. The shaft 400 has a cooling passage 410 formed therein along the longitudinal direction Is formed. A helical groove 411 is formed concavely in the hollow inner circumferential surface forming the cooling passage 410 of the shaft 400, or a wing-shaped helical baffle protruding inward is formed. Accordingly, when the shaft 400 is rotated together with the rotor 300, water can smoothly pass from one side of the shaft 400 to the other side, and the flow rate of the water passing through the helical groove 411 or the helical baffle can be increased can do.

The upper casing 500 and the lower casing 600 are hermetically sealed at the outer sides of the casings 500 and 600, which are engaged with the open both sides of the outer housing 100. At this time, grooves may be formed in the casings 500 and 600, and the sealing members 500a and 600a may be hermetically sealed so that an O-ring may be used as the sealing member.

Through holes 540 and 640 are formed at the center of the upper casing 500 and the lower casing 600 so that the shaft 400 is coupled to the shaft casing 400. Both sides of the shaft 400 are coupled to the upper casing 500 by the bushes 550 and 650, (500) and the lower casing (600) so as to smoothly rotate. At this time, on both sides of the rotor 300 coupled to the shaft 400, the sleeve 420 is coupled to the shaft 400 so that the upper casing 500, the lower casing 600, So that it can be smoothly rotated without contacting.

The inner housing 700 is spaced apart from the stator 200 and the rotor 300 so that the stator 200 is sealed and both sides of the inner housing 700 are connected to the upper casing 500 and the lower casing 600, And is sealed. That is, the stator 200 is enclosed by the outer housing 100, the upper casing 500, the lower casing 600, and the inner housing 700, and is disposed in the first space 110, which is a closed space.

Thus, the stator 200 is hermetically sealed, and water is not introduced from the outside. Since the stator 200 is coupled to the outer housing 100, the stator 200 can be cooled by discharging heat to water existing outside the outer housing 100 through the outer housing 100 . The shaft 400 and the rotor 300 can be cooled by the water passing through the cooling passage 410 formed to penetrate the shaft 400 and the spiral groove 411 formed in the cooling passage 410 The protruding spiral baffle accelerates the flow rate of water and increases the flow rate. In addition, since the helical groove 411 or the helical baffle serves to increase the heat exchange area, the cooling efficiency is improved.

As described above, the stator 200, the rotors 300 and the shafts 400, which are disposed on the outer side among the components constituting the submersible motor, can be uniformly cooled, It is possible to prevent the condensation phenomenon from occurring in the first space portion 110 where the first space portion 110 is disposed.

Accordingly, the submersible motor having improved cooling efficiency according to the present invention can prevent the performance of an underwater motor from being deteriorated by improving the cooling efficiency and cooling the rotor and stator of the underwater motor evenly, . Also, since no condensation is generated in the space where the stator 200 is hermetically sealed, the stator coil can be prevented from being damaged due to a short circuit.

The upper casing 500 and the lower casing 600 are formed with stepped portions 530 and 630 so as to be caught by the outer housing 100 and are inserted into the outer housing 100, 520, and 620. The first insertion portions 510 and 610 may be formed to protrude from the second insertion portions 520 and 620 and to be inserted into the inner housing 700.

As shown in the figure, the upper casing 500 and the lower casing 600 are formed in a multi-stepped shape. More specifically, the upper casing 500 has an upper outer diameter larger than an inner diameter of the outer housing 100 A second insertion portion 520 is formed to be inserted into the outer housing 100 at a lower side thereof and a second insertion portion 520 inserted into the inner housing 700 The first inserting portion 510 may protrude to the lower side of the first inserting portion 520. At this time, concave grooves are formed on the outer circumferential surfaces of the first and second insertion portions 510 and 520 to seal the sealing member 500a such as an O-ring, so that the sealing member 500a can be easily sealed when engaged. Similarly, the lower casing 600 may be formed in the same shape as the upper casing 500, and may be disposed symmetrically and coupled. At this time, the outer housing 100 may be firmly coupled to the upper casing 500 and the lower casing 600 by fastening means in a vertical direction or a horizontal direction.

Thus, the upper casing 500 and the lower casing 600 can be easily inserted into the outer housing 100 and the inner housing 700 to be easily engaged.

Both sides of the shaft 400 are coupled to the upper casing 500 and the lower casing 600 by bushes 550 and 650 or bearings so as to be rotatable, and between the shaft 400 and the upper casing 500, A fluid may be formed to pass between the upper casing 400 and the lower casing 600.

This is because the shaft 400 is coupled to rotate inside the bushes 550 and 650 so as to have a minute gap therebetween so that water can pass through the gap and, when coupled by a bearing, between balls formed between the inner ring and the outer ring of the bearing itself The water introduced between the bush 550 of the upper casing 500 and the shaft 400 flows into the second space portion 710 which is a space between the inner housing 700 and the rotor 300, Through the bush 650 of the lower casing 600 and the shaft 400, and then discharged. Thus, water can be passed through the rotor 300 and cooled, thereby further improving the cooling efficiency. At this time, grooves may be formed in the surfaces of the upper casing 500 and the lower casing 600 that contact the bushings 550 and 650 so that water flows along the grooves.

A wire outlet hole 561 is formed through the upper casing 500 so that the wires 210 connected to the coil of the stator 200 are drawn out and a wire 210 are inserted into the sealing member 580 such that the wires 210 are coupled to penetrate the cover 570 and the cover 570 is coupled to the upper casing 500 so that the sealing member 580 is in close contact Can be combined.

4 and 5, the electric wires 210 connected to the coil are drawn out to the outside through the upper casing 500, and an O-ring serving as the sealing member 580 is inserted into the electric wire 210 and the cover 570 The sealing member 580 is closely contacted with the upper casing 500 so that the sealing member 580 is hermetically sealed so that water does not flow into the interior through the wire drawing hole 561 formed in the upper casing 500.

Thus, there is an advantage that the electric wire 210 is easily drawn out to the outside of the upper casing 500 to close the electric wire drawing hole 561.

Also, the cover casing groove 560 may be formed concavely with the cover 570 inserted into the upper casing 500.

This allows the cover 570 to be inserted into the cover mounting groove 560 to fix the position so that the sealing member 580 is accurately brought into close contact with the periphery of the wire drawing-out hole 561 to be sealed. Further, the upper surface of the cover 570 can be the same as the upper surface of the upper casing 500, so that coupling with the pump or the like can be facilitated.

In addition, the cover 570 may be formed with a sealing member seat groove 571 so as to be recessed so that the sealing member 580 is inserted therein.

That is, since the sealing member 580 is inserted into the sealing member accommodation groove 571 of the cover 570, when the sealing member 580 is closely contacted by the cover 570, the sealing member 580 is pushed outward around the electric wire 210 It is possible to securely seal the periphery of the electric wire 210 and the electric wire draw-out holes 561 and 572.

The wire drawing holes 572 formed in the cover 570 and the wire drawing holes 561 formed in the upper casing 500 are arranged at the same angle with respect to the center of the cover 570 and the cover positioning groove 560 It is preferable that the fastening means 590 for tightly coupling the cover 570 to the upper casing 500 are also arranged at the same angle with respect to the center of the cover 570 so that a plurality of fastening means 590 are coupled.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1000: Submersible motor with improved cooling efficiency
100: outer housing 110: first space part
200: stator 210: wire
300: rotor
400: shaft
410: cooling channel 411: spiral groove
420: Sleeve
500: upper casing 500a: sealing member
510: first insertion portion 520: second insertion portion
530: step 540: through hole
550: Bush 560: Cover seat groove
561: Wire drawing-out ball 570: Cover
571: sealing member seat groove 572: wire drawing hole
580: sealing member 590: fastening means
600: lower casing 600a: sealing member
610: first insertion portion 620: second insertion portion
630: step 640: through hole
650: Bush
700: inner housing 710: second space

Claims (6)

An outer housing (100) hollow inside and open at both sides;
A stator 200 formed on the inner side of the outer housing 100 and wound with a coil;
A rotor 300 disposed inside the stator 200;
A shaft 400 coupled to the center of the rotor 300 and having a cooling passage 410 formed along the longitudinal direction thereof to form a helical groove 411 or a helical baffle in the cooling passage 410;
An upper casing 500 and a lower casing 600 coupled to both sides of the outer housing 100 so as to be hermetically sealed on the outside and coupled to both sides of the shaft 400 so as to be rotatable; And
An inner housing 700 spaced between the stator 200 and the rotor 300 and hermetically coupled to both the upper casing 500 and the lower casing 600; , ≪ / RTI >
The upper casing 500 and the lower casing 600,
The second insertion portions 520 and 620 are formed such that the step portions 530 and 630 are formed in the outer housing 100 and the second insertion portions 520 and 620 are inserted into the outer housing 100, Wherein the first inserting portions (510, 610) are formed to protrude and be inserted into the inner housing (700).
delete The method according to claim 1,
Both sides of the shaft 400 are coupled to the upper and lower casings 500 and 600 by bearings 550 and 650 so as to be rotatable,
Wherein a fluid is formed between the shaft (400) and the upper casing (500) and between the shaft (400) and the lower casing (600).
The method according to claim 1,
A wire outlet hole 561 is formed in the upper casing 500 so that electric wires 210 connected to the coil of the stator 200 are drawn out and an electric wire 210 drawn out to the outside of the upper casing 500, Are inserted into the sealing member 580 and the wires 210 are coupled to penetrate through the cover 570 and the cover 570 is coupled to the upper casing 500 so that the sealing member 580 is closely contacted And the cooling efficiency is improved.
5. The method of claim 4,
Wherein the cover casing groove (560) is formed concavely with the cover (570) inserted into the upper casing (500).
5. The method of claim 4,
Wherein the cover (570) is formed with a sealing member seat groove (571) concaved to receive the sealing member (580).

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