KR101243718B1 - drainage pumping apparatus - Google Patents

Abstract

The present invention relates to a drainage pump device for a drainage station for discharging water introduced into a sump tank through a discharge pipe, and includes a discharge pump and a discharge pipe for discharging the water pumped by the rotation of the pumping impeller of the drainage pump through the discharge pipe. , The drain pump is a motor unit for driving the pumping impeller to rotate, and the main flow passage is combined with the discharge pipe to surround the pumping impeller so that the water introduced through the inlet in the lower portion is transferred to the discharge pipe through the discharge pipe, and the rotation of the pumping impeller Partial discharge formed to discharge the pumped water from the lower part of the main flow path to the outside of the main flow path of the delivery pipe so that some of the rising water is discharged to the pumping area under the drain pump to form a vortex It has a pumping housing provided with a sub-channel for the purpose. According to such a drainage pump device for a drainage station, a part of the water pumped by the rotation of the pumping impeller is distributed so as to form a vortex in the pumping area between the lower part of the discharge pipe and the bottom of the sump to suppress the sedimentation of the soil in the pumping area. In addition, it provides an advantage to increase the discharge efficiency through the discharge pipe of the soil.

Description

Drainage pumping apparatus for pumping station

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pump station drain pump apparatus, and more particularly, to a pump station drain pump apparatus capable of suppressing deposition of deposits in a region to be pumped.

Generally, the drainage station collects the drainage flowing from the surrounding area into the sump, and pumps the collected water to flow to the drainage, river or river.

These drainage stations also purify or collect water as needed and use it as agricultural or industrial water or prevent flooding.

In general, the forced drainage method of a drainage station is provided with a structure in which a damper is installed on an inflow path into which water is introduced, and a collecting tank is installed at the rear of the dust collector and a pump for pumping the water stored in the collecting tank into the drainage channel.

However, in the case of the soil inflow with water is not removed even by the dust collector, it is introduced into the sump tank, so that the soil is deposited on the bottom of the sump tank over time, and when the inlet of the pump is blocked by the sediment deposition, the pump It is inconvenient to be unable to operate and to remove the sediment in the sump periodically.

The present invention was devised to improve the above problems, and an object thereof is to provide a drainage pump apparatus for a pumping station capable of suppressing deposition in the pumping area of the earth and sand introduced into the sump.

In order to achieve the above object, a pumping station drain pump apparatus according to the present invention includes a drainage pump apparatus for draining a drainage station for discharging water introduced into a collection tank through a discharge pipe; A discharge pipe for discharging the water pumped by the rotation of the pumping impeller of the drain pump through the discharge pipe, wherein the drain pump comprises: a motor unit for rotationally driving the pumping impeller; The main flow passage is coupled to the discharge pipe to surround the pumping impeller so that water introduced through the inlet of the lower part is transferred to the discharge pipe through the discharge pipe, and part of the water rising by the rotation of the pumping impeller is The pumping is provided with a partial discharge sub-flow path formed to discharge the water pumped from the lower part of the main flow path to a different path from the main flow path of the discharge pipe to the outside to discharge to the pumping area of the lower portion of the drain pump A housing;

According to one aspect of the invention, the discharge pipe is connected in communication with the discharge pipe and the motor unit is installed therein, from the lower portion of the discharge pipe so as to surround the portion facing the sub-channel of the pumping housing It further comprises an auxiliary pipe portion extending downward, the auxiliary pipe portion is provided to be spaced apart from the bottom surface of the water collection tank, the outer circumferential surface partitioned with the main flow path to discharge the water discharged through the sub-channel to the outside The vortex forming hole is formed so that it may be.

In addition, the motor unit includes a motor body provided with a stator and a rotor inside the motor frame opened up and down; An upper housing coupled to close the upper portion of the motor frame and having an upper bearing rotatably supporting a shaft coupled to the rotor of the motor body; A lower housing coupled to close the lower part of the motor frame and having a lower bearing supporting the shaft; A cooling chamber formed to have a main cooling space by surrounding the motor frame at a lower portion of the lower housing and filled with cooling oil; Cooling oil installed in the cooling chamber to extend upwardly toward the motor frame so that the cooling oil filled in the cooling chamber rises along the outer wall of the motor frame and forms a circulating flow path descending to the inner wall of the cooling chamber. Circulating bulkheads; A cooling impeller coupled to the shaft on the cooling chamber to rotate the cooling oil along the cooling oil circulation partition by rotation, wherein the pumping housing is coupled to the shaft extending below the cooling chamber. It is coupled with the lower portion of the cooling chamber so that the water introduced from the lower portion of the pumping impeller is divided into the main channel and the sub channel.

Preferably, the upper surface of the pumping impeller further includes an auxiliary cooling blade formed to protrude upward to cool the bottom surface of the cooling chamber by rotating water introduced in conjunction with the rotation of the pumping impeller.

Preferably, the pumping housing is coupled between the cooling chamber and the delivery pipe to form the main flow path, and the main flow path which is allowed to rise by the rotation of the pumping impeller between the cooling chamber and the inner wall of the delivery pipe. A main portion having an inner diameter that is extended from the cooling chamber so as to be transferred to the cooling chamber, and the inner portion of which is gradually narrowed as it proceeds downward; And a sub-part coupled to the main part and extending downward to form the sub-channel communicating with the outside between the lower end of the main part.

According to an aspect of the present invention, the pumping housing has a larger inner diameter than the lower end of the main part of the upper end of the sub-part so that a gap between the upper end of the sub-part and the lower end of the main part forms the sub-channel. It is formed to.

In another embodiment, the pumping housing is formed such that an upper end of the sub part is formed to have an inner diameter smaller than a lower end of the main part so that a gap between the top of the sub part and the bottom of the main part forms the sub channel.

According to the drainage pump device for a pumping station according to the present invention, the sedimentation of the pumping area by distributing a part of the water pumped by the rotation of the pumping impeller to form a vortex between the bottom of the discharge pipe and the bottom of the sump through the sub-channel In addition, it provides an advantage to increase the discharge efficiency through the discharge pipe of the soil.

1 is a cross-sectional view showing a drain pump station to which a drain pump device according to a first embodiment of the present invention is applied;
Figure 2 is a cross-sectional view showing a part of the discharge pipe is inserted the drain pump of Figure 1,
3 is a cross-sectional view showing a drain pump according to a second embodiment of the present invention,
4 is a partial cross-sectional view showing a drain pump according to a third embodiment of the present invention;
5 is a cross-sectional view showing a drain pump according to a fourth embodiment of the present invention.

Hereinafter, a drainage pump apparatus of a pump station according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in more detail.

1 is a cross-sectional view showing a drain pump station to which the drain pump device according to the first embodiment of the present invention is applied, and FIG. 2 is a cross-sectional view showing a part of a discharge pipe into which the drain pump of FIG. 1 is inserted.

1 and 2, the pump station 100 includes a vibration suppressor 110, a collection tank 120, and a drain pump device 200.

The pumping station 100 is pumped by the drainage pump device 200 through the inflow path 102 and the water collected in the water collecting tank 120 via the vibration suppressor 110 to the drainage path 130 through the discharge pipe 125. It is equipped with a structure for discharge.

Reference numeral 105 denotes a hydro drain for natural drainage.

The vibration damper 110 is a water collecting tank 120 and an inflow path 102 so that foreign matters contained in the water introduced through the inflow path 102 can be removed by a rake that rotates the foreign matter larger than the screen size of the screen in an endless track. It is provided between, and the structure of the damper 110 is known, and detailed description is abbreviate | omitted.

The water collecting tank 120 is formed to store water introduced through the vibration suppressor 110, and a drain pump device 200 is installed to be spaced apart from the bottom surface 122.

The drain pump device 200 is configured to discharge the water introduced into the sump tank 120 to the drainage path 130 through the discharge pipe 125 located above the sump tank 120.

The drain pump device 200 includes a discharge pipe 210, an auxiliary pipe part 211, and a drain pump 220.

The delivery pipe 210 is formed in a tubular shape of a hollow tube, and a drain pump 220 is embedded therein.

The discharge pipe 210 and the discharge pipe 125 through the drain hole 212 formed on the upper side to discharge the pumped water by the rotation of the pumping impeller 271 of the drain pump 220 through the discharge pipe 125 It is connected in communication.

The lower end of the delivery pipe 210 may be connected in communication with the main flow path 292 of the pumping housing 280.

The auxiliary pipe part 211 extends downwardly integrally from the lower part of the delivery pipe 210 so as to surround the part facing the sub flow path 294 of the pumping housing 280.

The auxiliary pipe part 211 is installed to be spaced apart from the bottom surface of the water collecting tank 120, and the space between the sub-channel 294 on the outer circumferential surface extending downwardly to be partitioned from the main channel 292 and the discharge pipe 210 ( A plurality of vortex forming holes 216 are formed along the circumferential direction to discharge the water discharged from the sub flow passage 294 to the outside through the 214.

 The vortex forming holes 216 formed in the auxiliary pipe portion 211 are radially formed along the outer circumferential surface, and the inner side is high and the outer side surface is low so that the introduced water is discharged radially downward around the auxiliary pipe portion 211. It is formed to be inclined.

The drain pump 220 is mounted in the delivery pipe 210, and includes a motor unit 230 and a pumping housing 280.

The motor unit 230 is capable of rotationally driving the pumping impeller 271 by the rotation of the motor.

The motor unit 230 includes a motor body 240, an upper housing 251, a lower housing 252, a cooling chamber 260, a cooling impeller 263, and a cooling oil circulation partition 265.

The motor main body 240 has a stator 243 and a rotor 245 installed inside the motor frame 241 that is open in a hollow cylindrical shape.

Reference numeral 247 denotes a power supply line for supplying power to the stator 243.

In the center of the rotor 245, a shaft 249 extending downward into the pumping housing 280 to be described later is integrally coupled to the rotor 245.

The upper housing 251 closes the upper part of the motor frame 241, and is formed to have an outer diameter greater than that of the motor frame 241, and is coupled to an upper end of the cooling chamber 260 to be described later.

An upper bearing 253 is rotatably supported at the center bottom of the upper housing 251 to rotatably support the shaft 249 coupled with the rotor 245 of the motor body 240.

Reference numeral 255 denotes a sealing ring installed between the upper end of the motor frame 241 and the upper housing 251.

The lower housing 252 is coupled to the lower portion of the motor frame 241 to close the lower portion of the motor frame 241.

The lower bearing 257 which supports the shaft 249 is installed in the center upper part of the lower housing 252.

The cooling chamber 260 extends in a direction in which the inner diameter extends about the shaft 249 so as to be spaced apart from the lower portion of the lower housing 252 at the lower portion of the lower housing 252, and extends upward to be coupled to the upper housing 251. The motor frame 241 is spaced apart from the outer surface of the motor frame 241 so as to have a main cooling space 264.

Reference numerals 268 and 269 are sealing members that can prevent leakage of cooling oil through a portion of the shaft 249 that rotates at high speed, and are fixed to the shaft 249 to rotate together with the shaft 249, and A mechanical seal may be applied to fit the joints of the fixing ring portions to be mated to prevent leakage.

Cooling oil, for example, oil is filled in the main cooling space 264 of the cooling chamber 260.

The cooling impeller 263 is coupled to the shaft 249 in the main cooling space 264 formed by the cooling chamber 260 and forms a rising vortex in conjunction with the rotation of the shaft 249 to circulate the cooling oil. It is circulated along the partition 265.

The cooling oil circulation partition 265 is installed upward in the cooling chamber 260 in parallel with the outer surface of the motor frame 241 so that the cooling oil filled in the main cooling space 264 of the cooling chamber 260 is rotated. It is formed to form a circulation flow path that rises along the outer wall of 241 and then descends to the inner wall of the cooling chamber 260.

A through hole 266 is formed at a lower end of the cooling oil circulation partition 265 so that the cooling oil descending on the inner wall of the cooling chamber 260 can be moved toward the cooling impeller 263.

In this cooling structure, the cooling oil is circulated by descending after passing through the outer surface of the motor frame 241 and the upper frame 251, thereby improving the cooling ability, thereby operating the motor main body 240 by malfunction or inadvertent operation even when water is not introduced. It provides the advantage of preventing overheating.

The pumping impeller 271 is coupled to the shaft 249 extending downward from the lower portion of the cooling chamber 260 to pump water introduced through the inlet 282 under the pumping housing 280 by the rotation of the shaft 249. do.

Pumping impeller 271 is a cooling chamber 260 by rotating the water introduced in conjunction with the rotation of the pumping impeller 271 on the upper surface of the pumping wing 272 to enable the cooling function of the cooling chamber 260 in addition to the pumping function An auxiliary cooling vane 274 protruding upward is formed to cool the bottom of the bottom.

The pumping housing 280 is coupled between the lower portion of the cooling chamber 260 of the motor unit 220 and the discharge pipe 210 to surround the pumping impeller 271.

The pumping housing 280 is lifted by the rotation of the main flow passage 292 and the pumping impeller 271 to allow the water introduced through the lower inlet 282 to be transferred to the discharge pipe 125 through the discharge pipe 210. Some of the water is discharged to the pumping area and the periphery of the drain pump 220 to form a vortex in the soil stacked in the pumping area to suppress the stacking of the soil while the main flow path (292) A partial discharge sub-path 294 is formed to discharge the water pumped to the outside in a path different from the main path 292 leading to the discharge pipe 210 from the lower portion.

The water discharged through the sub channel 294 is discharged to the outside through the vortex forming through-hole 216 formed in the auxiliary pipe portion 211.

That is, the pumping housing 280 divides water introduced from the lower part of the pumping impeller 271 coupled to the shaft 249 extending to the lower portion of the cooling chamber 260 into the main flow passage 292 and the sub flow passage 294. It is coupled with the lower portion of the cooling chamber 260 to supply.

Here, the sub channel 294 is preferably formed at a position higher than the lower end of the pumping impeller 271.

The pumping housing 280 may be divided into a main part 284 and a sub part 286.

The main part 284 has an inner diameter that is larger than that of the cooling chamber 260 so that the water that is raised by the rotation of the pumping impeller 271 can be transferred between the cooling chamber 260 and the inner wall of the discharge pipe 210. The edge is in close contact with or coupled to the inner wall of the delivery pipe 210, the inner diameter gradually extends narrower as the discharge pipe 210 proceeds downward to form a main flow path 292, the main flow path 292 The coupling chamber 260 is coupled to the cooling chamber 260 through a plurality of coupling bars 282 extending radially spaced apart from each other.

In addition, the upper edge portion of the main portion 284 is formed in a rib shape in close contact with the inner wall of the delivery pipe 210, and is sealed with the inner wall of the delivery pipe 210 by a packing member.

The sub portion 286 is coupled to the main portion 284 and extends downwardly so as to form a sub flow passage 294 communicating with the inner wall of the auxiliary pipe portion 211 between the lower end of the main portion 284. have.

Reference numeral 288 denotes a coupling bar for coupling the sub portion 286 and the main portion 284 to have a gap forming the sub flow passage 294.

The lower end of the sub portion 286 is formed with a rib in close contact with the inner wall of the auxiliary pipe portion 211.

In the example shown, the upper end of the sub-part 286 has a larger inner diameter than the lower end of the main part 284, so that the gap between the upper end of the sub-part 286 and the lower end of the main part 284 is sub-flow path 294. To form. The sub channel 294 may be formed in the form of a plurality of through holes spaced apart from each other.

Alternatively, as shown in FIG. 3, the upper end of the sub-part 286 has a smaller inner diameter than the lower end of the main part 284, so that a gap between the upper end of the sub-part 286 and the lower end of the main part 284 is formed. Of course, it can be formed to be a sub-channel (294).

Here, although the area between the outer circumferential surface of the main portion 284 and the outer circumferential surface of the sub portion 286 and the auxiliary pipe portion 211 has an empty space, unlike this, the auxiliary pipe portion 211 and the wall form having no space are different. When the sub-channel 294 is formed along the wall so as to extend to the vortex forming hole 216 of the auxiliary pipe portion 211.

According to such a drainage pump device, a portion of the water rising through the inlet 282 when the pumping impeller 271 rotates is passed through the sub-channel 294 and the vortex forming hole 216 and the lower portion of the discharge pipe 210 The earth and sand introduced together with the water by the vortices formed in the lower region of the discharge pipe 210 by being discharged to the pumping area between the bottom surface 122 of the 120 and the periphery thereof is dispersed and the inside of the discharge pipe 210 together with the water. Suction into the furnace is facilitated, and stacking of deposits is suppressed.

On the other hand, unlike the illustrated example, the motor unit 230 equipped with the rotor and stator of the drain pump 220 is installed outside the delivery pipe 210 as shown in FIG. 4, and the delivery pipe from the motor unit 230 is shown. The structure in which the pumping housing 280 is coupled to the lower portion of the discharge pipe 210 may be applied to surround the pumping impeller 271 coupled to the lower end of the shaft 249 extending into the 210.

In addition, the auxiliary pipe portion is omitted, the pumping housing 280 coupled to the lower portion of the delivery pipe 210 supplies water to the delivery pipe through the main flow path 292, the sub-flow path 294 is formed in direct communication with the outside Of course, the structure can be applied.

Here, the sub flow path 294 is formed such that the discharge direction is discharged in the direction toward the lower portion of the collecting tank 120.

In addition, a sealing process is performed between the shaft 249 and the discharge pipe 210 that are rotatably installed to penetrate the discharge pipe 210.

In addition, as shown in FIG. 5, the discharge pipe 210 may be formed to have an elbow-shaped main flow path 292, and have a gap between the pumping housing 280 and the cooling chamber 260. Of course, the structure formed 294 can be applied.

110: damper 120: water tank
200: drain pump

Claims (7)

delete In the drainage pump device for drainage to discharge the water introduced into the sump through the discharge pipe,
A drain pump;
And a discharge pipe for discharging the water pumped by the rotation of the pumping impeller of the drainage pump through the discharge pipe.
The drain pump is
A motor unit for rotationally driving the pumping impeller;
The main flow passage is coupled to the discharge pipe to surround the pumping impeller so that water introduced through the inlet of the lower part is transferred to the discharge pipe through the discharge pipe, and part of the water rising by the rotation of the pumping impeller is The pumping is provided with a partial discharge sub-flow path formed to discharge the water pumped from the lower part of the main flow path to a different path from the main flow path of the discharge pipe to the outside to discharge to the pumping area of the lower portion of the drain pump A housing;
The discharge pipe is connected in communication with the discharge pipe and the motor unit is installed therein,
And an auxiliary pipe portion extending downward from a lower portion of the discharge pipe so as to surround a portion of the pumping housing opposite to the sub flow path.
The auxiliary pipe part is installed to be spaced apart from the bottom surface of the water collection tank, the outer peripheral surface partitioned from the main flow passage is characterized in that the vortex forming hole is formed to discharge the water discharged through the sub flow path to the outside Drainage pump device for drainage station. The method of claim 2, wherein the motor unit
A motor main body having a stator and a rotor installed inside the motor frame opened up and down;
An upper housing coupled to close the upper portion of the motor frame and having an upper bearing rotatably supporting a shaft coupled to the rotor of the motor body;
A lower housing coupled to close the lower part of the motor frame and having a lower bearing supporting the shaft;
A cooling chamber formed to have a main cooling space by surrounding the motor frame at a lower portion of the lower housing and filled with cooling oil;
Cooling oil installed in the cooling chamber to extend upwardly toward the motor frame so that the cooling oil filled in the cooling chamber rises along the outer wall of the motor frame and forms a circulating flow path descending to the inner wall of the cooling chamber. Circulating bulkheads;
A cooling impeller coupled to the shaft on the cooling chamber to rotate the cooling oil along the cooling oil circulation partition by rotation;
The pumping housing is coupled to the lower portion of the cooling chamber to divide and supply water introduced from the lower portion of the pumping impeller coupled to the shaft extending to the lower portion of the cooling chamber into the main flow passage and the sub flow passage. Drainage pump device for drainage. According to claim 3, The upper surface of the pumping impeller further comprises an auxiliary cooling wing formed to protrude upward to cool the bottom surface of the cooling chamber by rotating the water introduced in conjunction with the rotation of the pumping impeller; A drainage pump device for a drainage station, characterized in that. 5. The pump housing of claim 4 wherein the pumping housing is
The cooling is coupled between the cooling chamber and the delivery pipe to form the main flow path, and the water that is raised by the rotation of the pumping impeller may be transferred to the main flow path leading between the cooling chamber and the inner wall of the delivery pipe. A main portion having an inner diameter that extends from the chamber but extending downward as the inner diameter gradually progresses downward;
And a sub-part coupled to the main part to extend downwardly to form the sub-channel communicating with the outside between the lower end of the main part. 6. The pump housing of claim 5 wherein the pumping housing is
The upper end of the sub-part is larger than the lower end of the main part is formed so that the clearance gap between the upper end of the sub-part and the lower end of the main part to form the sub-channel. 6. The pump housing of claim 5 wherein the pumping housing is
The upper end of the sub-part is formed with a smaller inner diameter than the lower end of the main part so that the gap between the upper end of the sub-part and the lower end of the main part is formed to form the sub-channel.

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