KR102573673B1 - Submerged motor pump with heat dissipation structure - Google Patents

Abstract

The present invention relates to a submersible motor pump having a heat dissipation structure. Therefore, through the configuration of the upper heat dissipation means and the lower heat dissipation means, it is possible to prevent overheating occurring in the upper portion of the drive shaft and the lower portion of the upper bearing and the lower bearing installed at a certain distance downward from the top to enable the drive shaft to idle. , Through this, it is possible to stably prevent failure of main parts such as upper and lower bearing parts or terminal boards in the vicinity where overheating occurs, and also significantly increase the life of the device through overheating prevention and failure prevention. It can.

Description

Submerged motor pump with heat dissipation structure}

The present invention relates to a submersible motor pump having a heat dissipation structure, and more particularly, a plurality of upper heat dissipation means are applied to the upper side of an upper bearing housing of an upper finishing frame, and a plurality of lower heat dissipation means are applied along the lower circumference of the lower bearing housing. By being applied, through the configuration of the upper heat dissipation means and the lower heat dissipation means, it is possible to prevent overheating occurring in the installation part of the upper bearing and the lower bearing installed at the top of the drive shaft and the lower part at a certain distance downward from the top to enable the drive shaft to run idle. Through this, it is possible to stably prevent failures of main parts such as upper and lower bearing parts or terminal boards in the vicinity where overheating occurs, and also significantly increase the lifespan of the device through prevention of overheating and failure. It relates to a submersible motor pump having a heat dissipation structure to enable

In general, a submersible motor pump is a device that is directly placed in water to suck and transfer fluid without a separate suction pipe, and is mainly used for pumping cloudy water mixed with soil or dirt.

These submersible motor pumps are classified into various types such as deep wells, tap water pressurization, and drainage, depending on the purpose and purpose of use. Typically, the motor and impeller are driven by power supply, and the fluid is pumped into the casing by rotation of the impeller. is sucked and the sucked fluid is configured to be discharged to the outside through a discharge port formed in the casing.

In the case of a conventional submersible motor pump, the fluid is sucked while the impeller rotates by the power generated by the rotation of the drive shaft generated by the motor. Overheating occurs in the installation parts of the upper and lower bearings, which are installed at a lower distance, and accordingly, the upper and lower bearing parts or major components such as terminal boards around where overheating occurs are caused to fail.

In other words, in the conventional submersible motor pump, as overheating occurs in the upper and lower parts of the upper and lower bearings installed at the top of the drive shaft and the lower part at a certain distance downward from the top to enable the drive shaft to idle, the upper and lower bearing parts However, there was a problem that caused failure of major components such as terminal boards in the vicinity where overheating occurred.

Therefore, in order to enable the drive shaft to run idle, it is possible to prevent overheating occurring in the upper and lower parts of the upper and lower bearings, which are installed at the top of the drive shaft and at the lower part at a certain distance downward from the top, and through this, the upper and lower bearings or overheating There is a need for research and development of a submersible motor pump that can significantly increase the lifespan of the device while stably preventing failure of major parts such as terminal boards around which this occurs.

Korea Patent Registration No. 10-1596776 2016.02.17. registration. Korea Patent Registration No. 10-1732980 2017.04.27. registration. Korea Patent Registration No. 10-1416549 2014.07.01. registration. Korea Patent Registration No. 10-0198286 1999.02.27. registration.

In order to solve the above problems, the present invention applies a plurality of upper heat dissipation means to the upper side of the upper bearing housing of the upper finishing frame, and applies a plurality of lower heat dissipation means along the lower circumference of the lower bearing housing, so that the upper heat dissipation means and In order to enable the drive shaft to run idle through the configuration of the lower heat dissipation means, it has a heat dissipation structure to prevent overheating occurring at the upper end of the drive shaft and the lower part at a certain distance downward from the upper bearing and the installation part of the lower bearing. It is an object of the present invention to provide a submersible motor pump.

Another object of the technology according to the present invention is that while a plurality of upper heat dissipation means is applied to the upper side of the upper bearing housing of the upper finishing frame, a plurality of lower heat dissipation means is applied along the lower circumference of the lower bearing housing, so that the upper heat dissipation means and the lower heat dissipation means In order to allow the drive shaft to run idle through the configuration, it is possible to prevent overheating occurring in the upper and lower bearings installed at the top and bottom of the drive shaft at a certain distance downward from the top, so that the upper and lower bearings or overheating can be prevented. It is possible to stably prevent failures of major components such as terminal boards that occur, and to significantly increase the lifespan of devices through overheating prevention and failure prevention.

The present invention for achieving the above object is as follows. That is, the submersible motor pump having a heat dissipation structure according to the present invention includes a suction pipe communicating from the lower suction part to the upper discharge part to form a flow path of pumping fluid; an impeller having a plurality of wing parts disposed in the passage along the outer circumference of the body part and rotatably disposed in the suction pipe; The impeller is connected to the lower side, the drive shaft providing a rotational driving force of the impeller; a central casing disposed to surround an upper region of the impeller of the driving shaft; A lower bearing housing in which a circumferential portion is tightly fixed to the upper end of the central casing, a lower bearing for rotationally supporting the drive shaft is seated in the central portion, and a lower bearing cover is fixedly installed on the upper portion where the lower bearing is seated and opened; a seal chamber having an upper circumferential portion closely fixed to the lower portion of the lower bearing housing to form a sealing space having an airtight structure in which a mechanical seal for sealing a drive shaft is disposed; A motor frame having a lower end connected to the upper part of the lower bearing housing, a stator installed along the circumference inside the motor installation space, and a rotor fixed to the inside of the stator so as to surround the outer surface of the drive shaft; An upper finishing frame in which a lower circumference is closely fixed to the upper part of the motor frame, an upper bearing housing is provided in the center of the lower part, and an upper bearing cover is fixedly installed at the lower part opened by inserting the upper bearing upward into the central part of the upper bearing housing; A head cover having a circumferential portion closely fixed to the top of the upper closing frame so as to cover the open top of the upper closing frame; and a lower heat dissipation means provided under the lower bearing housing to dissipate heat generated from the lower bearing side.

At this time, the lower heat dissipation means is provided on the lower surface of the lower bearing housing, and is provided in plurality at a predetermined interval on the lower surface between the circumferential portion closely fixed to the upper end of the central casing of the lower bearing housing and the circumferential portion through which the drive shaft is installed. It is preferable to provide

Furthermore, the lower heat dissipation means is preferably provided as a plurality of plate-shaped heat dissipation fins, which are bent in a bent or zigzag type with respect to the shape of the heat dissipation fins.

In addition, it is preferable to further include an upper heat dissipation means provided on the upper part of the upper bearing housing so as to dissipate heat generated from the upper bearing side inserted upward into the central part of the upper bearing housing provided in the lower center of the upper finishing frame.

At this time, it is preferable that the upper heat dissipation means is provided as a plurality of heat dissipation fins provided on the upper surface of the upper bearing housing at regular intervals on the upper surface of the upper bearing housing.

Further, the upper heat dissipation means is provided as a plurality of heat dissipation fins, and it is preferable to provide a heat dissipation fin on a plate bent in a bent type or a zigzag type with respect to the shape of the heat dissipation fins.

The effect of the submersible motor pump having a heat dissipation structure according to the present invention is described as follows.

First, a plurality of upper heat dissipation means are applied to the upper side of the upper bearing housing of the upper finishing frame, and a plurality of lower heat dissipation means are applied along the lower circumference of the lower bearing housing so that the drive shaft is idling through the configuration of the upper heat dissipation means and the lower heat dissipation means. In order to enable this, it is possible to prevent overheating occurring at the upper end of the drive shaft and at the lower part of the upper bearing and the lower bearing installed at a certain distance downward from the upper end.

Second, as a plurality of upper heat dissipation means is applied to the upper side of the upper bearing housing of the upper finishing frame, a plurality of lower heat dissipation means is applied along the lower circumference of the lower bearing housing to enable the drive shaft to idle through the configuration of the upper heat dissipation means and the lower heat dissipation means. In order to prevent overheating occurring in the upper and lower parts of the drive shaft, which are installed at a certain distance downward from the top, and the installation part of the lower bearing, It is possible to stably prevent the failure of major parts of the device, and also significantly increase the lifespan of the device through prevention of overheating and failure.

1 is a cross-sectional view showing a submersible motor pump having a heat dissipation structure according to the present invention.
Figure 2 is a cross-sectional view showing the main part of the heat dissipation structure of the lower bearing housing part, which is the main part of the submersible motor pump having the heat dissipation structure according to the present invention.
Figure 3 is a cross-sectional view showing the main part of the heat dissipation structure of the upper bearing housing part, which is the main part of the submersible motor pump having the heat dissipation structure according to the present invention.
4 is a cross-sectional view showing a state of use of a submersible motor pump having a heat dissipation structure according to the present invention, which is installed inside a lower part of a column pipe installed in a collecting well of a drainage pumping station.

Hereinafter, a preferred embodiment of a submersible motor pump having a heat dissipation structure according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing a submersible motor pump having a heat dissipation structure according to the present invention.

Figure 2 is a cross-sectional view showing the heat dissipation structure of the lower bearing housing part, which is the main part of the submersible motor pump having the heat dissipation structure according to the present invention, Figure 3 is the upper part, which is the main part of the submersible motor pump having the heat dissipation structure according to the present invention It is a cross-sectional view of the main part showing the heat dissipation structure of the bearing housing part.

4 is a cross-sectional view illustrating a state of use of a submersible motor pump having a heat dissipation structure according to the present invention, which is installed inside a lower part of a column pipe installed in a collecting well of a drainage pumping station.

As shown in FIGS. 1 to 4, the submersible motor pump 1000 having a heat dissipation structure according to a preferred embodiment of the present invention has a lower bearing installed at a lower part spaced a certain distance downward from the top of the drive shaft to enable the drive shaft to idle. It is designed to prevent overheating occurring in the part, and is largely classified into a suction pipe 110, an impeller 120, a drive shaft 130, a central casing 140, a lower bearing housing 150, and a seal chamber 160. , A motor frame 170, an upper finishing frame 180, a head cover 190, and a lower heat dissipation means 200 are included.

Specifically, the suction pipe 110 communicates from the lower suction part 111 to the upper discharge part 113 to form a pumping fluid passage 115.

At this time, it is preferable that the upper and lower peripheral portions of the suction part 111 and the discharge part 113 facing each other are fixed by a fixing means composed of bolts and nuts.

And, the impeller 120 has a plurality of wing parts 123 disposed in the passage 115 along the outer circumference of the body part 121, and is rotatably disposed in the suction pipe 110.

At this time, the impeller 120 as described above is constrained by the impeller nut 120a fixed to the lower end of the drive shaft 130 through a screw connection or a separate bolt or other fixing means in a state connected to the lower side of the drive shaft 130. It is desirable to be

In addition, the impeller 120 is connected to the lower side of the driving shaft 130 and provides rotational driving force of the impeller 120 .

The central casing 140 is disposed to surround the upper region of the impeller 120 of the driving shaft 130 .

In addition, the lower bearing housing 150 has a circumferential portion closely fixed to the top of the central casing 140, and a lower bearing 151 for rotationally supporting the drive shaft 130 is seated in the central portion, and the lower bearing 151 is The lower bearing cover 153 is fixedly installed on the seated and opened upper part.

And the seal chamber 160 has an upper circumferential portion closely fixed to the lower portion of the lower bearing housing 150, and a sealing space portion of an airtight structure in which a mechanical seal 161 for sealing the drive shaft 130 is disposed (uncoded) ) to form.

In addition, the lower end of the motor frame 170 is connected to the upper part of the lower bearing housing 150, and the stator 171 is installed along the circumference inside the motor installation space, and the drive shaft 130 is installed inside the stator 171. ) The fixed rotor 172 is disposed so as to cover the outer surface of the.

At this time, the stator 171 and the rotor 172 are installed inside the motor frame 170 of a conventional submersible motor pump, and a detailed description thereof will be omitted.

On the other hand, the upper finishing frame 180 has a lower circumferential portion closely fixed to the upper portion of the motor frame 170, an upper bearing housing 181 is provided in the lower center, and an upper bearing ( 183) is inserted upward and the upper bearing cover 185 is fixedly installed at the opened lower part.

And, the head cover 190 is fixed in close contact with the upper end of the upper finishing frame 180 so as to cover the open top of the upper finishing frame 180 .

In the head cover 190 as described above, in particular, a cable 195 is installed through one upper side and an inspection cover 191 for opening and closing an inspection opening (unsigned) is provided on the other upper side.

That is, the head cover 190 is further provided with an inspection cover 191 for opening and closing the inspection opening (unsigned) on the other side of the upper part, so that the terminal board ( 189), etc., inspection and maintenance can be easily performed.

Meanwhile, the lower heat dissipation means 200 is provided below the lower bearing housing 150 to dissipate heat generated from the lower bearing 151 side.

The lower heat dissipation means 200 is provided on the lower part of the lower bearing housing 150, particularly on the lower surface, and penetrates the circumferential portion closely fixed to the upper end of the central casing 140 of the lower bearing housing 150 and the drive shaft 130. It is preferable to provide a plurality of heat dissipation fins with a predetermined interval on the lower surface between the installed circumferential portions.

In other words, it is preferable that the lower heat dissipation means 200 is integrally formed with the lower heat dissipation means 200 as a plate-shaped heat dissipation fin extending long with a predetermined thickness and width.

Furthermore, although not specifically shown in the drawing, the lower heat dissipation means 200 is provided as a plurality of plate-shaped heat dissipation fins, but is provided as a plate-shaped heat dissipation fin bent in a bent type or zigzag type with respect to the shape of the heat dissipation fins.

In addition, although not specifically shown in the drawing, the lower heat dissipation means 200 is provided as a separate heat sink (not shown) having a plurality of heat dissipation fins (not shown) at regular intervals on one side of the base plate (not shown) , It may be fixedly installed on the lower surface of the lower bearing housing 150 through a fixing means (not shown).

At this time, the fixing means (not shown) can be variously applied such as brazing, bolting, or fixing slots.

And although the lower heat dissipation means 200 is not specifically shown in the drawing, it is integrally provided with a plurality of heat dissipation fins at regular intervals on the lower surface of the seal chamber 160, or has a predetermined interval on one side of the base plate (not shown) It may be provided as a separate heat sink (not shown) equipped with a plurality of heat sink fins (not shown) and fixedly installed on the lower surface of the seal chamber 160 through a fixing means (not shown).

In this case, the fixing means (not shown) can be variously applied such as brazing, bolting, or fixing slots.

The submersible motor pump 1000 having a heat dissipation structure according to the present invention having the configuration as described above (1000) is, in particular, an upper bearing ( 183) It is important to be able to dissipate the heat generated from the side.

Accordingly, the submersible motor pump 1000 having a heat dissipation structure according to the present invention further includes an upper heat dissipation means 300 provided on the upper bearing housing 181.

At this time, the upper heat dissipation means 300 is provided on the upper surface of the upper bearing housing 181, particularly on the upper surface, and is preferably provided as a plurality of heat dissipating fins at regular intervals on the upper surface of the upper bearing housing 181. .

In other words, it is preferable that the upper heat dissipation means 300 is provided as a heat dissipation fin on a long plate having a predetermined thickness and width.

Since the upper heat dissipation means 300 as described above is further provided, it is possible to prevent a failure due to heat dissipation of the terminal board 189 spaced apart from the upper bearing housing 181.

Furthermore, although not specifically shown in the drawings, the upper heat dissipation means 300 as described above is provided as a plurality of plate-shaped heat dissipation fins, but may be provided as a plate-shaped heat dissipation fin bent in a bent type or zigzag type with respect to the shape of the heat dissipation fins will be.

In addition, although not specifically shown in the drawing, the upper heat dissipation means 300 is provided as a separate heat sink (not shown) having a plurality of heat dissipation fins (not shown) at regular intervals on one surface of the base plate (not shown) , It may be fixedly installed on the upper surface of the upper bearing housing 160 through a fixing means (not shown).

At this time, the fixing means (not shown) can be variously applied such as brazing, bolting, or fixing slots.

In addition, although not specifically shown in the drawing, the upper heat dissipation means 300 is provided on the upper surface of the terminal board 189 spaced apart from the upper bearing housing 181 of the upper finishing frame 180, the terminal board 189 It may be provided as a plurality of heat dissipation fins at regular intervals integrally without interference with mounting components on the upper surface.

Of course, the upper heat dissipation means 300 is provided as a separate heat dissipation fin and may be fixed to the upper surface of the terminal board 189 through a fixing means (not shown) without interference with mounting components.

At this time, it is preferable that the fixing means (not shown) is integrally provided with a fixing piece orthogonal to the lower end of the radiating fin, and is provided by soldering or bolting to fix the fixing piece to the fixing piece.

On the other hand, as shown in FIG. 4, the submersible motor pump 1000 having a heat dissipation structure according to the present invention configured as described above is a column pipe 20 installed as a piping structure in the sump 10 of the drainage pumping station. It is preferable to be installed for drainage, pumping, etc. on the lower side of the interior.

Of course, the submersible motor pump 1000 having a heat dissipation structure according to the present invention may be installed in various structures for various purposes such as deep wells, tap water pressurization, and drainage, depending on the purpose and purpose of use.

On the other hand, non-explained numeral 196 denotes a stuffing box, which is the same as a stuffing box applied to a conventional submersible motor pump, so a detailed description thereof will be omitted.

In addition, non-explained numeral 140a denotes a casing wear ring, and this casing wear ring 140a is interposed between the outside of the top of the body portion 121 of the impeller 120 and the inside of the open bottom of the central casing 140. .

According to the submersible motor pump having a heat dissipation structure according to the present invention having the configuration as described above, a plurality of upper heat dissipation means is applied to the upper side of the upper bearing housing of the upper finishing frame, and a plurality of lower parts are applied along the lower circumference of the lower bearing housing. As the heat dissipation means is applied, the overheating phenomenon occurring in the installation part of the upper and lower bearings installed at the upper end of the drive shaft and the lower part at a certain distance downward from the top in order to enable the drive shaft to run idle through the configuration of the upper heat dissipation means and the lower heat dissipation means It can be prevented.

Furthermore, as a plurality of upper heat dissipation means is applied to the upper side of the upper bearing housing of the upper finishing frame, a plurality of lower heat dissipation means is applied along the lower circumference of the lower bearing housing, thereby enabling the drive shaft to idle through the configuration of the upper heat dissipation means and the lower heat dissipation means. In order to prevent overheating occurring in the upper and lower parts of the drive shaft, which are installed at a certain distance downward from the top, and the installation part of the lower bearing, It is possible to stably prevent failure of the main parts of the device, and significantly increase the lifespan of the device through overheating prevention and failure prevention.

Although specific embodiments of the present invention have been described in detail above, the present invention is not limited thereto, and various modifications can be made to the present invention by those skilled in the art, and these modifications is included in the scope of the present invention.

1000: submersible motor pump
110: suction pipe 111: suction part
113: discharge part 115: flow path
120: impeller 121: body
123: wing part 120a: impeller nut
130: drive shaft 140: central casing
140a: casing wear ring 150: lower bearing housing
151: lower bearing 153: lower bearing cover
160: seal chamber 161: mechanical seal
170: motor frame 171: stator
172: rotor 180: upper finishing frame
181: upper bearing housing 183: upper bearing
185: upper bearing cover 189: terminal board
190: head cover 191: inspection cover
195: cable 196: stuffing box
200: lower heat dissipation means
300: upper heat dissipation means
10: collection well
20: column pipe

Claims (10)

A suction pipe 110 communicating from the lower suction part 111 to the upper discharge part 113 to form a pumping fluid flow path 115;
An impeller 120 having a plurality of wing parts 123 disposed in the passage 115 along the outer circumference of the body part 121 and rotatably disposed in the suction pipe 110;
The impeller 120 is connected to the lower side, the drive shaft 130 for providing a rotational driving force of the impeller 120;
a central casing 140 disposed to surround an upper region of the impeller 120 of the driving shaft 130;
The circumferential portion is closely fixed to the upper end of the central casing 140, the lower bearing 151 for rotationally supporting the drive shaft 130 is seated in the central portion, and the lower bearing 151 is seated on the open upper portion of the lower bearing cover ( 153) is fixedly installed in the lower bearing housing 150;
A seal chamber 160 having an upper circumferential portion closely fixed to the lower portion of the lower bearing housing 150 to form a sealing space of an airtight structure in which a mechanical seal 161 for sealing the drive shaft 130 is disposed;
The lower end is connected to the upper part of the lower bearing housing 150, the stator 171 is installed along the circumference inside the motor installation space, and the rotor is fixed inside the stator 171 to surround the outer surface of the drive shaft 130. a motor frame 170 in which the former 172 is disposed;
The lower circumference is tightly fixed to the upper part of the motor frame 170, the upper bearing housing 181 is provided in the center of the lower part, and the upper bearing 183 is inserted upward in the center of the upper bearing housing 181 to open the lower part. an upper finishing frame 180 in which the upper bearing cover 185 is fixedly installed;
A head cover 190 having a circumferential portion closely fixed to the top of the upper closing frame 180 so as to cover the open top of the upper closing frame 180; and
In order to dissipate heat generated from the lower bearing 151 side, it is provided at the bottom of the lower bearing housing 150 and includes a lower heat dissipation means 200 capable of dissipating heat to the sealing space formed by fixing the seal chamber,
To dissipate heat generated from the side of the upper bearing 183 installed upwardly inserted into the central part of the upper bearing housing 181 provided in the lower center of the upper finishing frame 180,
It further includes an upper heat dissipation means 300 provided on the upper bearing housing 181,
The upper heat dissipation means 300 is provided on the upper surface of the upper bearing housing 181,
Submersible motor pump having a heat dissipation structure, characterized in that provided by a plurality of heat dissipation fins at regular intervals on the upper surface of the upper bearing housing (181).
According to claim 1,
The lower heat dissipation means 200 is provided on the lower surface of the lower bearing housing 150,
It is characterized in that it is provided with a plurality of heat dissipation fins with a predetermined interval on the lower surface between the circumferential portion closely fixed to the upper end of the central casing 140 of the lower bearing housing 150 and the circumferential portion through which the drive shaft 130 is installed. A submersible motor pump having a heat dissipation structure.
According to claim 2,
The lower heat dissipation means 200 is provided as a plurality of plate-shaped heat dissipation fins,
A submersible motor pump having a heat radiation structure, characterized in that it is provided as a heat radiation fin on a plate bent in a bent type or zigzag type with respect to the shape of the heat radiation fin.
delete delete According to claim 1,
The upper heat dissipation means 300 is provided as a plurality of heat dissipation fins,
A submersible motor pump having a heat radiation structure, characterized in that it is provided as a heat radiation fin on a plate bent in a bent type or zigzag type with respect to the shape of the heat radiation fin.
According to claim 1,
The lower heat dissipation means 200 is a heat dissipation structure characterized in that it is provided as a separate heat sink having a plurality of heat dissipation fins at regular intervals on one surface of the base plate, and is fixed to the lower surface of the lower bearing housing 150 through a fixing means. Submersible motor pump having a.
According to claim 1,
The lower heat dissipation means 200 is integrally provided with a plurality of heat dissipation fins at regular intervals on the lower surface of the seal chamber 160, or is provided as a separate heat dissipation plate provided with a plurality of heat dissipation fins at regular intervals on one surface of the base plate to seal A submersible motor pump having a heat dissipation structure, characterized in that it is fixedly installed on the lower surface of the chamber 160 through a fixing means.
According to claim 1,
The upper heat dissipation means 300 is a heat dissipation structure characterized in that it is provided as a separate heat dissipation plate provided with a plurality of heat dissipation fins at regular intervals on one surface of the base plate, and is fixedly installed on the upper surface of the upper bearing housing 160 through a fixing means. Submersible motor pump having a.
According to claim 1,
The upper heat dissipation means 300 is provided on the upper surface of the terminal board 189 spaced apart from the upper bearing housing 181 of the upper finishing frame 180,
An underwater motor pump having a heat dissipation structure, characterized in that it is provided with a plurality of heat dissipation fins at regular intervals integrally without interference with mounting components on the upper surface of the terminal board (189).

Images