KR20180068510A - Water pump - Google Patents

Abstract

The present invention relates to an underwater pump. The underwater pump comprises: an upper cover; a motor unit coupled to the upper cover; and a pump unit connected to the motor unit. At the time, the motor unit comprises: a shaft having a rotor; a stator to which the shaft is inserted to electrically interact with the rotor so as to control rotation of the rotor; an upper bearing inserted into an upper end of the shaft; a head cover which is located on the upper bearing, on which the upper bearing is placed, and which comes in contact with the upper cover; a lower bearing inserted into a lower portion of the shaft; and a lower bearing housing in which the lower bearing is located.

Description

Underwater pump {WATER PUMP}

The present invention relates to an underwater pump.

Generally, submersible pumps are used to supply water to a desired place, and are widely used throughout the industry.

Such a submersible pump has a form in which it is installed so as to be submerged in water or a slurry, and a form in which the submerged pump is vertically moved up and down as needed to be submerged in water or slurry only when necessary. However, since both are in contact with water, Should be waterproof.

The submersible pump includes a motor shaft, a shaft rotated by the operation of the motor unit, and a pump unit located below the motor unit and rotated by the rotation of the shaft.

At this time, the upper bearing and the lower bearing, which are a pair of bearings, are mounted on the shaft, so that the rotation of the shaft can be smoothly performed.

Generally, since the shaft is roughly connected to the pump portion through the motor portion in the longitudinal direction, the upper bearing located at the upper portion of the shaft is installed mainly in the upper cover of the underwater pump, and the lower bearing is provided between the motor portion and the pump portion Located.

The motor unit includes a stator for controlling rotation of the rotor by electrical interaction between the rotor and the rotor connected to the shaft.

In addition, the pump unit is provided with an impeller connected to the lower end of the shaft.

Accordingly, when a current is applied to the stator to rotate the rotor, the shaft rotates, and the impeller fixedly connected to the shaft is rotated by the rotation of the shaft to rotate the pumping object, such as water, And then discharged to the discharge port.

Korean Registered Patent Publication No. 10-1054749 (filed on August 01, 2011, entitled "Underwater Motor Pump Bearing Unit")

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art.

Another object of the present invention is to provide a control device for controlling the operation of a submersible pump in contact with water inside a submersible pump to facilitate installation and downsizing of the submersible pump.

According to an aspect of the present invention, an underwater pump includes an upper lid, a motor unit coupled to the upper lid, and a pump unit connected to the motor unit. The motor unit includes a shaft on which a stator is mounted, A stator for controlling the rotating operation of the rotor by electrically interacting with the rotor, an upper bearing inserted and positioned at an upper end of the shaft, an upper bearing mounted on the upper bearing, A head cover spaced apart from the upper cover, a lower bearing inserted into the lower portion of the shaft, and a lower bearing housing in which the lower bearing is located.

The pump unit includes an impeller connected to the shaft, an impeller housing on which the impeller is mounted, and an elbow disposed on a side surface of the impeller housing and having a discharge hole.

The underwater pump may further include a terminal block located in a space formed between the top cover and the head cover and connected to a wiring for supplying an electric signal to the motor unit.

The submerged pump may further include a tube having a wiring insertion hole which is installed to penetrate through the upper lid and is connected to the terminal block through an external wiring.

The head cover may include a wiring discharge hole that passes through the head cover and discharges wiring connected to the motor unit to the upper cover.

The head cover may protrude downward from a lower surface of the head cover and include a protrusion having a hollow space, and the upper bearing may be located in the hollow space.

It is preferable that the shaft is not projected onto the upper surface of the head cover but is located in the space formed by the head cover.

The motor unit may further include a motor housing housing the stator, the shaft and the lower bearing housing, and a lubricant injecting unit located below the motor housing and having a lubricant injection hole.

The underwater pump may further include a water chamber inserted into the motor housing and a sealing device located between the lower bearing housing and the water chamber and having a shaft inserted therein to prevent the lubricant from flowing into the motor housing Preferably, a space between the lower bearing housing and the water chamber is connected to the lubricating oil injection hole.

According to this aspect, since the wiring connection to the motor unit is made easy through the terminal block, the time for manufacturing the underwater pump is shortened.

Since the upper bearing is located inside the head cover located at the lower portion of the upper cover, the height of the space formed between the upper cover and the head cover can be arbitrarily changed.

Therefore, an electronic device and an electric device for controlling the operation of the motor part can be incorporated in the closed space formed in the sealing device, so that downsizing of the submersible pump is realized and the degree of freedom of design is improved.

1 is a perspective view of an underwater pump according to an embodiment of the present invention.
Fig. 2 is a cross-sectional view taken along the line II-II of Fig. 1. Fig.
Figs. 3 and 4 are exploded perspective views of the underwater pump shown in Fig. 1, and are exploded perspective views in different directions.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but it should be understood that there may be other elements in between do. On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

Hereinafter, a submersible pump according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1, a submersible pump according to an embodiment of the present invention includes a motor unit 10, a pump unit 20 connected to the motor unit 10, and a plurality of And an upper cover 30 coupled to the motor unit 10 using a fastening hole H31 of the main body 31 and having a main body 31.

The motor unit 10 includes a head cover 11 disposed below the upper lid 30 and separating the upper lid 30 and the motor unit 10 from each other and a head cover 11 An upper bearing 13 passing through the inside of the stator 12 to be in contact with the head cover 11, a shaft 13 connected to the upper end of the upper bearing 13, 14, a rotor 15 fixedly connected to the shaft 14, a lower bearing unit 16 connected to the lower end of the shaft 14, a motor housing 17, and a motor housing 17 And a lubricating oil injecting portion 18 positioned thereon.

The head cover 11 is positioned between the upper lid 30 and the motor housing 17 so that the upper lid 30 and the motor housing 17 can be connected to each other.

The head cover 11 is spaced below the top cover 30 and has a protrusion 111 protruding downward at the bottom and having a hollow space. At this time, the empty space surrounded by the protruding portion 111 having a circular planar shape forms an upper bearing seat groove H11 on which the upper bearing 13 is seated.

The outer surface of the head lid 11 is located in contact with the inner surface of the main body 31 of the upper lid 30 and the inner surface of the main body 31 of the upper lid 30 and the outer surface of the head lid 11 So that the head cover 11 is positioned at the lower end of the side surface of the main body 31 of the upper cover 30. As a result, an empty space is formed between the main body 31 of the upper lid 30 and the head lid 11.

The head cover 11 is provided with a wiring discharge hole H111 for discharging a wiring for power supply for the operation of the motor unit 10 to the outside.

The wiring discharge hole H111 is formed in the upper portion of the head lid 11. [

The stator 12 has a substantially cylindrical shape having a hollow hole H12 completely passing through the stator 12 so that the rotor 15 can be inserted therein. As a result, the upper end and the lower end of the stator 12 are open.

The protrusion 111 of the head cover 11 is inserted into the hole H21 formed at the upper end of the stator 12 so that the stator 12 is engaged with the head cover 11. [

Windings 121 are wound on the upper and lower portions of the stator 12, respectively.

At this time, a wiring (not shown) connected to the coil wound around the winding part 121 is discharged to the wiring discharge hole H111 of the head cover 11. [

The upper bearing 13 is formed with a hole H13 in its center portion and is inserted into the upper end of the shaft 14 through the hole H13 and positioned in the upper bearing seat groove H11 of the head cover 11. [ The upper bearing 13 is mounted on the upper end of the shaft 14.

2, a space is located between the upper bearing 13 and the upper bearing seating groove H11. In this space, the upper bearing 13 is positioned in contact with the upper bearing 13 to limit the position of the upper bearing 13. [ An elastic member (not shown) such as a leaf spring exists to stably limit the position of the upper bearing 13.

Since the position of the upper bearing 13 is flexibly limited by such an elastic member, damage to the upper bearing 13 due to shock or the like caused by the rotation of the shaft 14 is reduced.

The shaft 14 on which the rotor 15 is mounted is inserted into the stator 12 through the hole H12 formed inside the stator 12. [

The shaft 14 passes through the inside of the fixing portion 12 until the upper bearing 13 mounted on the upper end of the shaft 14 is positioned in the upper bearing seating groove H11 formed in the projection 111, . At this time, the shaft 14 is not extended over the upper surface of the head cover 11, that is, not extended to the outside of the head cover 11, but is formed in a space formed by the head cover 11, H11).

When the shaft 14 is inserted into the stator 12 after the insertion operation of the shaft 14 is completed until the predetermined position is reached, the rotor 15 is positioned in the interior of the stator 12, And the rotor 15 are overlapped with each other at regular intervals.

When a power source (for example, three-phase power source) necessary for the operation is supplied through the stator 12 to which the wiring is connected, the rotor 15 is rotated by the electrical interaction between the stator 12 and the rotor 15, And the rotation of the shaft 15 is performed by the rotation of the rotor 15.

The lower bearing unit 16 includes a lower bearing cover 161 inserted into the lower end of the shaft 14, a lower bearing 162 inserted into the lower end of the shaft 14 and positioned in contact with the lower bearing cover 161, a lower bearing housing 164 having a snap ring 163 with a snap ring 163 underneath the snap ring 163 and a lower bearing seating groove H164 on which the lower bearing 162 is seated, A mechanical seal 165 inserted into the lower end of the shaft 14 through the housing 164, a water chamber 166 located below the sealing device 165, and a sealing device 166 And a blocking plate 167 mounted on the water chamber 166. [

The lower bearing cover 161 is inserted into a lower end portion of the shaft 14 through a hole formed in the center so as to define a mounting position of a lower bearing 162 disposed at a lower portion of the lower bearing cover 161. The lower bearing cover 161 covers a lower bearing 162, 162) and fix the position.

The lower bearing 162 is inserted into the lower end of the shaft 141 in contact with the lower bearing cover 161 so that the rotation of the shaft 14 together with the upper bearing 13 can be performed.

The snap ring 163 is positioned so as to surround the lower bearing 162 inserted therein so that the lower bearing 162 located therein is positioned at a predetermined position without departing from the position.

The lower bearing housing 164 has a protruding portion 1641 protruding downward from the lower surface and an inner space surrounded by the protruding portion 1641 forms a hollow space so that the hollow space is formed in the lower bearing seating groove H164 .

Accordingly, the lower bearing 162 is positioned in the lower bearing seat groove H164 so that the rotation of the shaft 14 is performed.

The lower bearing housing 164 is inserted into the motor housing 17 and fastened to the lower portion of the motor housing 17.

To this end, a plurality of coupling grooves H163 are formed in the peripheral portion of the lower bearing housing 164, and a corresponding one of the plurality of coupling grooves H163 (corresponding to the coupling grooves H163) H171) are formed.

Therefore, the motor part hinge 17 and the lower bearing housing 164 are fastened in the motor housing 17 using fastening means such as screws.

Accordingly, the fastening position of the shaft 15 coupled with the lower bearing housing 164 can be stably maintained.

2, the sealing device 165 prevents penetration of lubricating oil such as water or oil into the motor unit 10 and includes a through hole H165 through which a portion of the lower portion of the shaft 14 passes, Have

Therefore, since the lower portion of the shaft 14 is located through the through hole H165, the position of the shaft 14 is limited to the inside of the through hole H165 of the sealing device 165, so that the shaft 14 is in a predetermined position.

This sealing device 165 is inserted into the space enclosed by the protrusions 1641 of the lower bearing housing 164 at which time the sealing device 165 does not penetrate the lower bearing housing 164.

Thus, the upper position of the sealing device 165 is defined by the lower bearing housing 164.

The water chamber 166 prevents fluid such as water or slurry that has been introduced from the pump unit 20 from flowing into the lower bearing unit 16 side or the motor unit 10 side.

The water chamber 166 has a through hole H166 through which a portion of the lower portion of the shaft 14 is inserted and a protruding portion 1662 around the water chamber 166. The through hole H166 has a sealing device 165 are inserted.

At this time, since the sealing device 165 inserted into the through-hole H166 of the water chamber 166 does not penetrate the water chamber 166, the lower position of the sealing device 165 is determined by the water chamber 166 .

The sealing device 165 is positioned between the lower bearing housing 164 and the water chamber 166 so that the sealing device 165 is positioned between the lower bearing housing 164 and the water chamber 166, An empty space SP1 is formed. At this time, the empty space SP1 is substantially located inside the lubricant oil injecting portion 18 and is enclosed by the lubricant oil injecting portion 18 so as to be sealed.

As such, since the sealing device 165 is mounted in the water chamber 166, the shape of the inner surface surrounding the through-hole H166 of the water chamber 166 can be determined according to the shape of the sealing device 165 .

A plurality of fastening holes H1661 are formed at the edge of the water chamber 166 and the water chamber 1661 is fastened to the impeller housing 22 through these fastening holes H1661.

The blocking plate 166 is formed with a center hole for the sealing device 165 to be inserted therein and is inserted into the sealing device 165 and then placed on the projection 1662 of the middle portion of the water chamber 166, Thereby blocking the inflow of water to the portion 10.

Thus, the lower bearing unit 16 is located at the lower portion of the shaft 14, so that the rotation of the shaft 14 is smoothly performed together with the upper bearing 13 located at the upper portion of the shaft 14. [

Further, the lower bearing unit 16 allows the lower bearing 162 to be positioned at a predetermined position.

The motor housing 17 is a case of the motor unit 10 and includes a stator 12 into which a shaft 14 coupled with a rotor 15 and an upper bearing 13 is inserted, (16) is built in to protect the components mounted inside from external shocks and the like.

The outer surface of the upper portion of the motor housing 17 is provided with a plurality of fastening holes H17 which can be engaged with the upper lid 30 by using a fastening member B11 such as a bolt.

The number of the fastening holes H17 is equal to the number of fastening holes H31 of the upper lid 30 and the number of fastening holes H31 of the upper lid 30, .

As shown in FIGS. 1 and 2, a lubricating oil injecting portion 18 formed by extending a motor housing 17 downward is integrally formed at a lower portion of the motor housing 17.

As already described, there is a lubricating oil space SP1 in which lubricating oil, which is an empty space SP1, is contained in the lubricating oil injecting portion 18. [

The lubricant injection unit 18 is coupled to the water chamber 167 by using a coupling member B12 using a screw or the like with the water chamber 167. [

A lubricant oil injection hole H18 for inserting the fastening member B13 is formed on the outer circumferential surface of the lubricant oil injecting portion 18 (that is, the portion where the lower bearing unit 16 is located).

At this time, the lubricant oil injection hole H18 passes through the motor housing 17 in the thickness direction and passes through the lubricant space SP1.

Therefore, lubricating oil is injected into the lubricating oil space SP1 whenever necessary through the lubricating oil injecting hole H18, whereby lubricating oil is contained in the lubricating oil space SP1.

As shown in FIG. 2, a sealing device 165, which is coupled to a shaft 14 that penetrates itself, is located inside the lubricant oil injecting portion 18. Therefore, the sealing device 165 can be exposed through the lubricant oil injection hole H18.

Generally, a large amount of frictional heat is generated in the sealing device 165 in which the shaft 14 is built in due to the rotation operation of the shaft 14. [

However, since the sealing device 165 exposed to the lubricating oil space SP1 is in contact with the lubricating oil, it is possible to cool the frictional heat generated through the lubricating oil so that the sealing device 165 is protected.

The thickness of the lubricating film formed by the lubricating oil decreases to an appropriate thickness or less according to the rotation operation of the shaft 14, or the viscosity of the lubricating oil is decreased The rotation of the shaft 14 is adversely affected and a wear phenomenon of the sealing device 165 may occur.

However, in the case of this example, when additional injection of the lubricating oil is required, further injection of the lubricating oil into the lubricating oil space SP1 is facilitated through the lubricating oil injection hole H18 after releasing the fastening member B13.

Therefore, due to the lubricating oil injection hole H18, the lubricating oil is additionally supplied whenever necessary without decomposition of the underwater pump, so that the mechanical wear caused by the mechanical friction occurring during the rotation operation of the shaft 14, The risk of damage to the device 165 is reduced. Further, the generation of frictional heat due to the rotation operation of the shaft 14 or the like is reduced, and the service life of the underwater pump is prolonged.

The upper portion of the lubricating oil space SP1 is blocked by the lower bearing housing 164 and the lower portion of the lubricating oil space SP1 is blocked by the water chamber 166 so that the lubricating oil space SP1 is communicated with the lubricating oil injecting portion 18 The lubricating oil space SP1 in which the side portions are closed by the lubricating oil spaces SP1 is closed space of these components 164, 166 and 18 so that the injected lubricating oil is held only in the corresponding space SP1, So that the operation of the pump unit 20 located at the lower portion is not adversely affected.

In addition, the fluid introduced from the pump portion 20 by the water chamber 166 is blocked from flowing into the lubricant space SP1.

The pump unit 20 includes an impeller 21 located below the water chamber 166 of the motor unit 10 and connected to the shaft 14, an impeller housing 22 located below the impeller 21, an impeller housing An elbow 23 located at the side of the impeller housing 22 and having a discharge hole H23, a suction cover 24 located below the impeller housing 22, And a pedestal 25 which is coupled and has a suction hole H25 formed therein.

The impeller 21 has an insertion hole H21 through which the shaft 14 is inserted in the center portion thereof.

A lower portion of the impeller 21 is provided with a protrusion 211 for positioning the shaft 14 at a predetermined position by using a nut N11 and a retainer 213 is inserted into the upper portion of the impeller 21. [ And has a protruding portion 212.

Since the impeller 21 is coupled to the shaft 14 using the key 214, the shaft 14 has a groove H14 through which the key 214 is inserted, The inner circumferential surface of the protruding portion 212 on the upper portion of the main body 21 also has a groove H212 into which the key 214 is inserted.

At this time, the groove H212 is an empty space connected to the insertion hole H21, and thus forms a part of the insertion hole H21.

The key 214 is inserted into the groove H212 of the impeller 21 and the key 214 inserted into the groove H212 of the impeller 21 is inserted into the corresponding groove H14 of the shaft 14 , The connection between the impeller 21 and the shaft 14 is completed.

A thread groove into which the nut N11 is inserted is formed in a lower portion of the shaft 14 inserted into the insertion hole H21 of the impeller 21 and penetrating the impeller 21. [

The lower end of the shaft 14 is connected to the impeller 21 because the nut N11 is inserted into the lower portion of the shaft 14 through which the impeller 21 penetrates.

When the shaft 14 is rotated by the mechanical connection between the impeller 21 and the shaft 14, the rotational force of the shaft 14 is transmitted to the impeller 21 to rotate the impeller 21, A suction force is generated by the rotation of the pedestal 21 and the object to be pumped is sucked into the suction hole H25 of the pedestal 25.

The impeller housing 22 is formed with an impeller mounting groove H22 as an empty space through which the impeller 21 can be mounted.

A water chamber 166 is inserted into the impeller housing 22 to connect the water chamber 166 and the impeller housing 22 to each other through a fastening hole H1661 formed in the edge of the water chamber 166 and a fastening hole H221 formed in the impeller housing 22, .

The motor housing 17 having the lubricating oil injecting portion 18 is mounted on the protruding portion 221 of the impeller housing 22 and then coupled to each other by screws or the like. As a result, the motor portion 10 stably stays on the impeller housing 22.

The discharge hole H23 of the elbow 23 is connected to the impeller mounting groove H22 which is a space formed inside the impeller housing 22 to discharge the pumping object sucked into the impeller housing 22 to the outside.

2, the suction cover 24 is inserted into the impeller housing 22 and coupled with the impeller housing 22. At this time, the suction cover 24 is coupled with the impeller housing 22 using a fastening member such as a screw, do.

The suction cover 24 has a suction hole H24 connected to the suction hole H25. Therefore, due to the suction cover 24, the suction object sucked through the suction hole H25 is introduced into the impeller housing 22 through the suction hole H25.

Due to the suction cover 24, the suction operation of the pumping object is performed more easily.

As shown in FIG. 2, the lower portion of the shaft 14 extends through the stone cover 24.

The suction hole H25 formed in the pedestal 25 is also connected to the inner space of the impeller housing 22 so that the suction hole H25 is connected to the discharge hole H23 through the inner space of the impeller housing 22 .

Due to this, the object to be pumped is sucked toward the suction hole (H25) by the centrifugal force by the rotation operation of the impeller (21) and is discharged through the discharge hole (H23) of the elbow (23).

The shaft 14 does not penetrate the head cover 11 because the upper bearing 13 fastened to the upper portion of the shaft 14 is located in the head cover 11. In this case, The shaft 14 does not extend to the main body 31 of the upper lid 30 and is located between the head lid 11 and the suction cover 24. [

As a result, the length of the shaft 14 is reduced compared with the case where the head cover 11 is not present, so that the rotation operation of the shaft 14 can be made easier.

The upper lid 30 has a main body 31, a tube 32 attached to the upper portion of the main body 31 and a terminal block 33 located inside the main body 31.

The main body 31 has a circular planar shape in which an inner space has a hollow space and a lower surface is opened, and is joined to a motor housing 17 having a cylindrical shape. To this end, the main body 31 is provided with a plurality of fastening holes H31 corresponding to the fastening holes H71 of the motor housing 17 at the lower end of the outer surface, (H17, H31) are coupled by fastening devices such as screws.

A tube insertion hole H32 through which the tube 32 is inserted is formed in the upper portion of the main body 31. [

The tube insertion hole H32 is formed so as to completely penetrate the main body 31 of the upper lid 30 and is connected to the enclosed space inside the main body 31. [

The tube 32 has a substantially cylindrical shape having a hole penetrating the center thereof, that is, a wiring insertion hole H321.

Therefore, the wiring supplied with power from the Korea Electric Power Corporation through the wiring insertion hole H321 is inserted into the interior of the main body 31 from the outside, and the wiring introduced from the outside is connected to the motor portion 10 via the terminal block 33. The terminal block 33 is electrically connected to the semiconductor device 10,

Thus, the power required for the operation of the motor unit 10 is supplied from the outside, and the operation of the motor unit 10 is performed.

The terminal block 33 is a connection block for electrically and physically connecting the wiring inserted through the tube 32 and the wiring discharged from the motor portion 10 to each other.

Since the terminal block 33 in which the electric connection with the motor unit 10 is performed is located inside the upper lid 30 as described above, the electrical connection relationship between the wiring on the side of the motor unit 10 and the wiring introduced from the outside And the sealing function of the wiring is improved by the upper lid 30.

That is, in the case where the upper bearing is present in the main body 31 of the upper lid 30, since there is no head cover 11, the distance between the stator 12 and the main body 31 of the upper lid 30 The physical and electrical connections between the wires are made.

However, in this case, the connection between the wirings may be broken by the rotator 15 located in the shaft 14 and rotating.

However, in this embodiment, since the main body 31 of the upper lid 30 is separated from the motor portion 10 by the head cover 11, the connection between the wires is damaged by the operation of the rotor 15 The problem does not occur.

Since the terminal module 33 is located in the main body 31 of the upper lid 30 which is a space separated from the motor unit 10, the electrical wiring operation is facilitated.

The upper bearing 13 is located in the head cover 11 located under the upper cover 30 instead of being located in the empty space in the upper cover 30. [

As a result, an empty space is formed between the upper cover 30 and the head cover 11.

Therefore, the height of the space formed between the top cover 30 and the head cover 11 is determined by the position of the top cover 30.

Thus, if necessary, a cylindrical sealing device having a desired height and a hollow space at the center is positioned between the upper lid 30 and the head lid 11, so that the sealed space, in which intrusion of the pumping object is prevented, .

Therefore, a built-in electronic apparatus such as a control unit and a communication unit for controlling the operation of the motor unit 10 in an enclosed space formed in the sealing apparatus, and an electric apparatus can be built.

As described above, since the electronic device and the electric device related to the operation of the underwater pump are embedded in the underwater pump, the underwater pump can be downsized and the degree of freedom of design is improved.

The upper lid 30 and the head lid 11 can be formed without any need to change the shape of the upper lid 30 in order to form a desired closed space between the upper lid 30 and the head lid 11. [ Only the height of the sealing device is adjusted. Therefore, the upper lid 30 is not required to be newly formed, and thus the manufacturing cost of the underwater pump is not increased.

In the drawing, reference numerals O11 to O15 denote O-rings which are positioned between two adjacent contact elements to improve adhesion and sealing force.

Also, for the sake of convenience of the drawings, fastening members, washers, additional O-rings and the like have been omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

10: motor section 20: pump section
30: upper cover 11: head cover
12: stator 13: upper bearing
14: shaft 15: rotor
16: Lower bearing unit 17: Motor housing
18: lubricating oil injecting part 161: lower bearing cover
162: lower bearing 164: lower bearing housing
165: sealing device 166: water chamber
33: Terminal block

Claims (9)

Top cover,
A motor unit coupled to the upper cover,
And a pump unit
Lt; / RTI >
The motor unit includes:
A shaft on which a rotor is mounted,
A stator for inserting the shaft to electrically interact with the rotor to control rotation of the rotor,
An upper bearing inserted and positioned at an upper end of the shaft,
A head cover positioned above the upper bearing to seat the upper bearing and spaced apart from the upper cover,
A lower bearing inserted into the lower portion of the shaft, and
The lower bearing housing
. ≪ / RTI > The method of claim 1,
The pump unit includes an impeller connected to the shaft,
An impeller housing on which the impeller is seated, and
An elbow with a discharge hole located on the side of the impeller housing
. The method of claim 1,
And a terminal block located in a space formed between the top cover and the head cover and connected to a wiring for supplying an electric signal to the motor unit. 4. The method of claim 3,
Further comprising a tube having a wiring insertion hole which is installed to penetrate through the upper lid and which is connected to the terminal block through an external wiring. 4. The method of claim 3,
And the head cover includes a wiring discharge hole that passes through the head cover and discharges wiring connected to the motor unit to the upper cover. The method of claim 1,
Wherein the head cover includes a protrusion protruding downward from a lower surface of the head cover and having a hollow space,
The upper bearing is located in the empty space
Underwater pump. The method of claim 1,
Wherein the shaft is not protruded above the top surface of the head cover and is located within the space defined by the head cover. The method of claim 1,
The motor unit includes a motor housing in which the stator, the shaft, and the lower bearing housing are housed,
And a lubricating oil injecting portion which is located below the motor housing and has a lubricating oil injecting hole,
Further comprising an underwater pump. The method of claim 1,
A water chamber inserted in the motor housing, and
And a sealing device disposed between the lower bearing housing and the water chamber and having a shaft inserted therein to prevent the lubricating oil from flowing into the motor unit.
Further comprising:
And a space between the lower bearing housing and the water chamber is connected to the lubricant injection hole.

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