KR102530324B1 - Vertical multi-stage pump comprising lower bearing for supporting shaft - Google Patents

Abstract

The present invention relates to an upright multistage pump comprising a lower metal bearing, and more specifically, to an upright multistage pump comprising a lower metal bearing, which may stably suppress the vibration of a rotary shaft and an impeller during the operation process of a pump. To this end, provided in the present invention is an upright multistage pump comprising a lower metal bearing, which is characterized by comprising: a pump unit in which a plurality of impellers are arranged in a stacked structure in a pump case having an inlet and an outlet, and the plurality of impellers are rotated to suck and discharge fluid; a motor unit which is installed at the upper portion of the pump unit, and comprises a rotary shaft coupled to the plurality of impellers, wherein the rotary shaft sequentially penetrates the plurality of impellers to be inserted into a support hole formed at the lower end portion of the pump case; and a lower metal bearing which is installed at the support hole, and is coupled to the rotary shaft to support the rotary shaft.

Description

Vertical multi-stage pump comprising lower bearing for supporting shaft}

The present invention relates to a vertical multistage pump, and more particularly, includes a lower metal bearing supporting a rotary shaft at the lower part of a rotary shaft installed to be coupled with a plurality of impellers in a vertical position, wherein the lower metal bearing is an upper bearing and a lower bearing It is made of a double structure, and the lower bearing is coupled to the pump case to suppress flow, and the fluid flowing into the pump freely flows into the lower metal bearing through the flow path formed in the lower bearing while cooling and lubricating the vertical multi-stage. It's about the pump.

In general, vertical multi-stage pumps are arranged in a structure in which a plurality of impellers are stacked inside, and a pump unit configured to suck and discharge fluid through rotation of the impeller, and an upper portion of the pump unit to generate power for rotation of the impeller It consists of a motor part that becomes

The motor unit is made in the form of a general motor including a rotor and a stator, and a rotating shaft installed in the center of the rotor extends into the pump unit and is connected to a plurality of impellers.

On the other hand, since the rotating shaft extending from the motor unit to the pump unit sequentially passes through the plurality of impellers and is coupled to each of the impellers, the plurality of impellers disposed inside the pump unit are connected to each other through one rotation shaft and rotate while pumping the fluid.

As described above, the lower end of the rotating shaft extending from the motor part to the pump part and coupled with the plurality of impellers passes through the lowermost impeller without any special support and ends as it is.

As described above, since the conventional input multi-stage pump is composed of a free end without special support at the lower end of the rotation shaft, vibration can easily occur during the pumping process of the fluid. Therefore, not only a high-rigidity structure of the rotation shaft itself is required, but also a bearing supporting the rotation shaft. There is a problem that a high rigidity structure is required.

Registered Patent Publication No. 10-2078203 (2020.02.19. Notice) Registered Patent Publication No. 10-1881086 (Announced on July 23, 2018)

The present invention has been made in consideration of the above problems, and an object of the present invention is to provide a vertical multistage pump including a lower metal bearing capable of stably suppressing vibrations of a rotating shaft and an impeller during pump operation.

Another object of the present invention is a vertical multi-stage pump including a lower metal bearing in which two metal bearings support the lower end of the rotating shaft in a double structure, and the fluid flowing by the operation of the pump is circulated between the rotating shaft and the metal bearing. is in providing

The present invention, which achieves the above object and eliminates the conventional drawbacks, has a plurality of impellers arranged in a stacked structure inside a pump case in which a suction port and a discharge port are formed, and the plurality of impellers rotate while the fluid a pump unit configured to inhale and discharge; A motor unit installed on the upper part of the pump unit and having a rotational shaft coupled to a plurality of impellers, wherein the rotational shaft sequentially passes through the plurality of impellers and is inserted into a support hole formed at a lower end of the pump case; And a lower metal bearing installed in the support hole and coupled to the rotation shaft to support the rotation shaft;

On the other hand, in the vertical multistage pump including the lower metal bearing, the lower metal bearing is formed in a disk-shaped structure in which a first hole is formed in the center portion to be inserted and coupled in a form in which a portion of the lower end of the rotation shaft passes through, and the rotation shaft is jammed An upper bearing supported in the form of supporting the rotating shaft across the chin; It is located at the lower part of the upper bearing, and includes a small-diameter portion inserted into and coupled to the support hole, and an upper surface formed as an integral structure on the upper part of the small-diameter portion and in close contact with the bottom surface of the upper bearing, so that the upper bearing is formed on the lower part. It may be composed of; a lower bearing composed of a large diameter part supported by and a second hole formed in a structure penetrating the large diameter part and the small diameter part so that a part of the lower end of the rotating shaft is fitted and coupled.

Meanwhile, in the vertical multistage pump including the lower metal bearing, the lower bearing includes: a plurality of inlets that pass through the small diameter portion in a radial direction and are distributed in a circumferential direction of the small diameter portion; It further includes; a plurality of distribution grooves distributed in the circumferential direction of the small diameter part on the inner circumferential surface of the second hole, connected from the large diameter part to the small diameter part, and formed to be connected to the inlet, and installed in the support hole at the lower end of the pump case. A plurality of connectors may be formed that are connected to the inlet of the lower bearing and form a passage through which a part of the fluid flowing into the inlet flows into the inlet.

Meanwhile, in the vertical multistage pump including the lower metal bearing, a plurality of pumping grooves extending in the radial direction of the upper bearing and extending from the first hole to the outer circumferential surface of the upper bearing and distributed in the circumferential direction of the upper bearing are It may be further formed on the bottom of.

Meanwhile, in the vertical multistage pump including the lower metal bearing, the support hole is formed in a bottom block manufactured separately from the pump case to form a raised portion protruding from the inner bottom of the pump case, and the bottom block is assembled by the pump case. It can be made to be formed on the bottom of the pump case by doing.

According to the present invention having the above characteristics, since the lower end of the rotation shaft extending from the motor unit to the pump unit and coupled with the plurality of impellers is supported by the lower metal bearing installed at the lower end of the pump case, the rotation shaft and the impeller during operation of the pump Vibration of the can be stably suppressed, through which the durability of the pump can be remarkably improved.

In addition, a part of the fluid sucked through the inlet of the pump case is introduced between the lower bearing and the rotating shaft through the connector and the inlet, lubricating and cooling, reducing the frictional resistance between the rotating shaft and the lower bearing, resulting in a more stable rotational support structure. By implementing the vibration of the pump can be more effectively reduced, and the durability of the pump can be further improved.

1 is an internal structure diagram of a vertical multi-stage pump according to a preferred embodiment of the present invention;
2 is a detailed view of 'A'part;
3 is an exploded perspective view showing the structure of a lower metal bearing according to the present invention;
4 is an internal structure diagram showing the structure of a lower metal bearing according to the present invention;
5 is a perspective view showing a structure in which a pumping groove is further formed in an upper bearing according to the present invention;
Figure 6 is an internal structure diagram of a lower metal bearing configured using an upper bearing with a pumping groove further formed.

Hereinafter, a preferred embodiment of the present invention will be described in detail in connection with the accompanying drawings. In describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

1 is an internal structure diagram of a vertical multi-stage pump according to a preferred embodiment of the present invention, FIG. 2 is a detailed view of 'A' part, FIG. 3 is an exploded perspective view showing the structure of a lower metal bearing according to the present invention, FIG. is an internal structural diagram showing the structure of the lower metal bearing according to the present invention, Figure 5 is a perspective view showing a structure in which pumping grooves are further formed in the upper bearing according to the present invention, Figure 6 is a pumping groove is further formed using the upper bearing It shows the internal structure of the configured lower metal bearing.

A vertical multistage pump according to a preferred embodiment of the present invention is composed of a pump unit 100, a motor unit 200, and a lower metal bearing 300.

The pump unit 100 has a suction port 111 formed on one side of the lower end and a plurality of impellers 120 stacked while being spaced apart from each other in the vertical direction inside the pump case 110 having the discharge port 112 formed on one side of the upper end. It consists of being placed.

Meanwhile, in the case of the pump case 110 according to a preferred embodiment of the present invention, a support hole 113 for installing the lower metal bearing 300 is formed at the inner lower end, and the support hole 113 is the pump case 110 ) Is formed to be located in the central portion of the raised portion 114 formed to protrude from the inner bottom central portion of the.

In addition, the ridge 114 is formed with a connector 115 forming a passage through which a portion of the fluid introduced through the suction port 111 can flow directly to the support hole 113, and the connector 115 A plurality of them are formed to be dispersed in the circumferential direction of the raised portion 114 . Therefore, the fluid flowing into the inlet 111 flows into the support hole 113 through the connector 115 in various directions.

As such, for easy processing of the ridge 114, the support hole 113, and the connector 115 located on the inner bottom of the pump case 110, the ridge 114, the support hole 113, and the connector 115 ) After manufacturing the formed floor block 400 separately from the pump case 110, the manufactured floor block 400 is assembled and fixed to the lower end of the pump case 110 to form a raised portion 114 on the inner floor. And the pump case 110 formed with the support hole 113 and the connector 115 may be configured.

In the motor unit 200, a stator and a rotor (not shown) are installed inside the motor case, are installed to be fixed to the rotor, rotate together with the rotor, and are inserted into the pump unit 100 to have a plurality of impellers 120 ) It is configured to include a rotating shaft 210 coupled with.

On the other hand, the rotating shaft 210 sequentially passes through the plurality of impellers 120 disposed inside the pump unit 100, and then is inserted into the support hole 113 formed at the lower end of the pump case 110, The diameter of the insertion portion 211 inserted into the support hole 113 is formed to have a smaller diameter than the impeller coupling portion 212 to which the impeller 120 is coupled, so that the diameter of the insertion portion 211 and the impeller coupling portion 212 Due to the difference, a locking jaw is formed in the boundary area between the insertion part 211 and the impeller coupling part 212.

The lower metal bearing 300 is installed in the support hole 113 of the pump case 110 to support the lower end of the rotating shaft 210, and is composed of an upper bearing 310 and a lower bearing 320, and the upper bearing Both 310 and lower bearing 320 are made of metal.

The upper bearing 310 is formed in a disk-shaped structure in which a first hole 311 is formed in the central portion through which the insertion part 211 of the rotating shaft 210 is inserted and coupled, and the first hole 311 The inner diameter of is formed in the same size as the outer diameter and the insertion portion 211.

The upper bearing 310 is coupled to the insertion part 211 and rotates together with the rotation shaft 210, but is straddled by a chin formed in the boundary area between the impeller coupling part 212 of the rotation shaft 210 and the insertion part 211. It is installed on the rotating shaft 210 to support the impeller coupling part 212 in a form supported from the bottom.

In addition, a plurality of pumping grooves 312 may be formed on the bottom surface of the upper bearing 310 to be distributed in a circumferential direction, and each pumping groove 312 is a radius of the upper bearing 310 on the bottom surface of the upper bearing 310. It is formed to extend in the direction and is configured to form a flow path connecting the inner surface and the outer surface of the upper bearing 310 .

The lower bearing 320 has a two-stage structure of a large diameter portion 321 and a small diameter portion 322, the small diameter portion 322 is fitted into the support hole 113, and the large diameter portion 321 is The second hole 323 protrudes upward from the support hole 113 and is formed to support the lower bearing 320 while making contact with the lower bearing 320 and forms a space in which the rotary shaft 210 is inserted and coupled. It consists of a structure formed through the neck portion 321 and the small diameter portion 322.

More specifically, the small diameter portion 322 is inserted into the support hole 113 and configured in a cylindrical shape having an outer diameter equal to the inner diameter of the support hole 113 so as to be fitted.

The large-diameter portion 321 has a disk-shaped structure having an outer diameter larger than that of the small-diameter portion 322, and is formed as an integral structure on the upper portion of the small-diameter portion 322. The upper surface of the large-diameter portion 321 is in close contact with the lower surface of the upper bearing 310 to provide a function of supporting the upper bearing 310 below.

The second hole 323 is formed to pass through the large-diameter portion 321 and the small-diameter portion 322 and has the same inner diameter as the outer diameter of the insertion portion 211 of the rotary shaft 210.

In the lower bearing 320 configured as described above, while the fluid circulates between the lower bearing 320 and the rotating shaft 210, frictional resistance and heat generated between the rotating shaft 210 and the lower bearing 320 are reduced. An inlet 324 and a distributing groove 325 are further formed on the lower bearing 320.

The inlet 324 has a structure penetrating the small diameter portion 322 in the radial direction, and a plurality of the inlets 324 are formed to be distributed in the circumferential direction of the small diameter portion 322 .

The inlet 324 is formed on the raised portion 114 of the pump case 110 at a position where the small diameter portion 322 is completely coupled to the support hole 113 and the lower bearing 320 is completely assembled to the pump case 110. It is formed to match the formed connector 115 so that the fluid introduced through the connector 115 is guided to the inside of the small diameter portion 322 through the inlet 324.

The dispersion grooves 325 extend vertically on the inner circumferential surface of the second hole 323 and extend from the large diameter portion 321 to the small diameter portion 322, and a plurality of the distribution grooves 325 are distributed in the circumferential direction of the small diameter portion 322. Formed, each distribution groove 325 is formed to be connected to the inlet 324.

Meanwhile, in FIG. 2, four inlets 324 are formed to be distributed in the circumferential direction of the small diameter portion 322, and four distribution grooves 325 are formed to be distributed in the inner circumferential surface of the second hole 323, so that the inlet 324 and the distribution groove 325 are connected in a one-to-one structure is shown. According to this structure, the fluid introduced through the inlet 324 is distributed up and down through the distribution groove 325.

In the vertical multistage pump including the lower metal bearing according to the present invention configured as described above, the lower end of the rotary shaft 210 extending from the motor unit 200 to the pump unit 100 and coupled with the plurality of impellers 120 is the lower metal As the bearing 300 is additionally supported by the pump case 110, vibration generated during operation of the pump can be significantly reduced, and durability of the pump can be improved as vibration generated during operation of the pump is reduced. there will be

On the other hand, during the operation of the pump, some of the fluid sucked through the inlet 111 by the rotation of the impeller 120 is introduced into the connector 115 formed on the ridge 114, and the inlet 324 connected to the connector 115 It is discharged between the rotating shaft 210 and the lower bearing 320 through ), and is distributed up and down the lower bearing 320 by the distribution groove 325, and thus between the rotating shaft 210 and the lower bearing 320. As a uniform lubricating layer is formed on the entire surface, smooth lubrication and cooling functions are provided.

Meanwhile, when a plurality of pumping grooves 312 are formed on the bottom surface of the upper bearing 310, the flow flows between the upper bearing 310 and the lower bearing 320 through the distribution groove 325 and flows into the pumping groove 312. The fluid is forcibly discharged into the pump case 110 by the centrifugal force generated by the upper bearing 310 rotating together with the rotating shaft 210 .

As the fluid in the pumping groove 312 is forcibly discharged by the centrifugal force as described above, a relatively low pressure is formed inside the pumping groove 312, and as a result, the fluid in the distribution groove 325 is discharged from the pumping groove 312. As it flows naturally into the fluid, a flow in which the fluid circulates is formed, enabling smoother lubrication and cooling.

As described above, the vertical multi-stage pump according to the present invention is a very useful invention that enables more quiet and stable operation by reducing vibration generated during operation of the pump and improves durability of the pump.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone having ordinary knowledge in the art to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, such changes are within the scope of the claims.

<Description of symbols for main parts of drawings>
100: pump unit 110: pump case
111: suction port 112: discharge port
113: support hole 114: ridge
115: connector 120: impeller
200: motor unit 210: rotation shaft
300: lower metal bearing 310: upper bearing
311: first hole 312: pumping groove
320: lower bearing 321: large diameter part
322: small diameter portion 323: second hole
324: inlet 325: distribution groove
400: floor block

Claims (5)

A pump in which a plurality of impellers 120 are arranged in a stacked structure inside a pump case 110 in which a suction port 111 and a discharge port 112 are formed, and the plurality of impellers 120 suck and discharge fluid while rotating. part 100; It is installed on the upper part of the pump unit 100 and has a rotating shaft 210 coupled to a plurality of impellers 120, but the rotating shaft 210 sequentially penetrates the plurality of impellers 120 to form a pump case 110. ) Motor unit 200 formed to be inserted into the support hole 113 formed at the lower end of the; And a lower metal bearing 300 installed in the support hole 113 and coupled with the rotation shaft 210 to support the rotation shaft 210;
The lower metal bearing 300 is formed in a disk-shaped structure in which a first hole 311 is formed in the center of the lower end of the rotation shaft 210 to be inserted and coupled, and is attached to the locking jaw of the rotation shaft 210. An upper bearing 310 that spans and supports the rotating shaft 210 in a form of supporting; and a small-diameter portion 322 positioned below the upper bearing 310 and inserted into and coupled to the support hole 113, and formed in an integral structure on the upper portion of the small-diameter portion 322, and the upper bearing 310 ) The large diameter part 321 and the small diameter part 322 so that the large diameter part 321 supporting the upper bearing 310 from the lower side and a part of the lower end of the rotating shaft 210 are fitted and coupled, including the upper surface that is in close contact with the bottom surface of the ). It consists of; a lower bearing 320 made of a second hole 323 formed in a structure passing through,
The lower bearing 320 includes a plurality of inlets 324 that penetrate the small diameter portion 322 in a radial direction and are distributed in a circumferential direction of the small diameter portion 322; A plurality of distribution grooves are formed on the inner circumferential surface of the second hole 323 to be distributed in the circumferential direction of the small diameter part 322, and connected from the large diameter part 321 to the small diameter part 322 and connected to the inlet 324. 325; further includes, and the lower end of the pump case 110 is connected to the inlet 324 of the lower bearing 320 installed in the support hole 113, and a part of the fluid flowing into the inlet 111 is passed through the inlet Vertical multi-stage pump including a lower metal bearing, characterized in that a plurality of connectors 115 forming a passage for flowing to (324) are formed.
delete delete The method of claim 1,
A plurality of pumping grooves 312 extending in the radial direction of the upper bearing 310 extend from the first hole 311 to the outer circumferential surface of the upper bearing 310 and are distributed in the circumferential direction of the upper bearing 310. Vertical multi-stage pump including a lower metal bearing, characterized in that further formed on the bottom surface of the bearing (310).
The method of claim 1,
The support hole 113 is formed in the bottom block 400 manufactured separately from the pump case 110 so as to form a raised portion 114 protruding from the inner bottom of the pump case 110, so that the bottom block 400 Vertical multi-stage pump including a lower metal bearing, characterized in that formed on the bottom of the pump case 110 by assembling by the pump case 110.

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