KR20160061769A - Pump - Google Patents

Abstract

According to one embodiment of the present invention, a pump is provided. According to one embodiment of the present invention, the pump comprises: a housing of which one side is connected to an inlet pipe and the other side is connected to an outlet pipe, wherein water is introduced to the inlet pipe and the water is leaked from the outlet pipe; and a plurality of impellers connected to a rotational shaft to be stored inside the housing and moving the water from the inlet pipe to the outlet pipe. A drain hole can be formed in at least one among the housing and the rotational shaft. The purpose of the present invention is to provide a pump effectively removing foreign substances existing inside the pump.

Description

Pump {Pump}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a pump, and more particularly, to a pump having a structure capable of effectively removing foreign substances present inside a pump.

Generally, the pump sucks and pressurizes the fluid as the impeller combined with the rotation axis of the motor receives the driving force, and discharges the fluid in one direction. At least one filter is installed on the system or piping including such a pump, and foreign substances contained in the fluid flowing into the pump through the filter are removed. However, if the system has a large pipe diameter, it is not easy to create a filter that passes through the entire pipe. In this case, a by-pass line having a relatively smaller diameter than the pipe diameter is created to filter the fluid.

However, there is a limit in removing foreign matter through the filter and the bypass line, and nuts, washers, inclusions, etc. can be inserted into the piping during disassembling and assembling components during maintenance of the system. Foreign matter such as nuts, washers, etc. inserted into the piping enters the pump together with the fluid and directly impacts the impeller. Particularly, in the case of a multi-stage pump having two or more impellers, foreign matter may be interposed between the impeller and the impeller, which may cause the pump to fail. Therefore, there is a problem that the operation of the system is interrupted to remove the foreign substances inside the pump, and the pump and the system must be separated after all the fluid is taken out.

Korean Registered Patent No. 10-0850279 2008. 07. 29

Disclosure of Invention Technical Problem [8] The present invention provides a pump capable of effectively removing foreign matter present in a pump.

The technical objects of the present invention are not limited to the technical matters mentioned above, and other technical subjects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a pump including: a housing having an inlet pipe through which water flows in one side and an outlet pipe through which water flows in the other side; And a plurality of impellers which are accommodated in the housing and move the water from the inlet pipe to the outlet pipe, wherein at least one of the housing and the rotary shaft has a drain hole.

The circulation pipe may be connected to the drain hole at one end and connected to the inlet pipe, and a first filter unit connected to the circulation pipe to remove foreign matter.

The drain hole may be located in a direction normal to the rotating surface of the impeller.

A plurality of impeller accommodation portions may be provided between the plurality of impellers, and the drain holes may be located in at least one of the plurality of impeller accommodation portions.

The rotation shaft may be formed as a hollow tube, and the drain hole may be formed on one side and the outflow hole may be formed on the other side.

A plurality of impeller receiving portions are formed between the plurality of impellers, and the drain holes are located adjacent to the partition walls. The outlet holes may be formed outside the impeller receiving portion.

A hollow open-close pipe inserted in the inside of the rotating shaft and having an open / close hole coinciding with the drain hole; and a closed-type open / close pipe inserted into the drain hole to rotate or slidably move the open- And may further include a driving unit.

And a second filter unit formed inside the rotating shaft to remove foreign matter flowing into the rotating shaft.

According to the present invention, it is possible to effectively remove foreign substances present inside the pump. Therefore, damage of the impeller due to foreign substances present inside the pump and failure of the pump can be prevented, and the life of the pump can be increased. In addition, since the conventional operation of stopping the operation of the system and removing the fluid and removing the pump and the system in order to remove foreign matter is omitted, the working efficiency can be improved.

1 is a view showing a pump according to an embodiment of the present invention.
Figs. 2 and 3 are operation diagrams for explaining the operation of the pump of Fig. 1. Fig.
4 is a view showing a pump according to another embodiment of the present invention.
5 is a partially enlarged view of the pump of Fig.
6 and 7 are operation diagrams for explaining the operation of the pump of FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, a pump according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3. FIG.

1 is a view showing a pump according to an embodiment of the present invention.

A pump 1 according to an embodiment of the present invention is a pump that sucks and pressurizes fluid to discharge fluid in one direction and is installed between an inlet pipe 100 and an outlet pipe 200. The pump 1 can effectively remove foreign substances present inside the housing 10. [ Therefore, damage of the impeller 20 due to foreign substances present inside the housing 10 and failure of the pump 1 can be prevented, and the service life of the pump 1 can be increased. In addition, since the conventional operation of stopping the operation of the system and removing the fluid and then separating the pump and the system from each other is omitted in order to remove the foreign matter, there is a feature that the working efficiency can be improved.

Hereinafter, the pump 1 will be described in detail with reference to Fig.

A pump (1) according to the present invention includes a housing (10), an impeller (20), and a drive motor (30).

The housing 10 is a tubular member and is connected to an outflow pipe 200 to which an inflow pipe 100 for flowing water into one side is connected and a water flows out to the other side. The housing 10 is formed with a flow space 11 through which water flows in a central portion thereof and the flow space 11 extends along the longitudinal direction of the housing 10 and connects the inlet pipe 100 and the outlet pipe 200 to each other The water can be connected and connected. That is, the water introduced through the inlet pipe 100 flows out through the outlet pipe 200 through the flow space 11. Although the inlet pipe 100 and the outlet pipe 200 are shown as coupled to the lower side of the housing 10 arranged in the vertical direction in the drawing, the present invention is not limited thereto and the structure may be variously modified. For example, the inlet pipe 100 may be coupled to the lower side of the housing 10 arranged in the vertical direction, and the outlet pipe 200 may be coupled to the upper side of the housing 10, . At this time, the path of the flow space 11 may be deformed depending on the position where the inlet pipe 100 and the outlet pipe 200 are coupled to the housing 10. For example, when the inlet pipe 100 and the outlet pipe 200 are respectively coupled to the lower side of the housing 10 arranged in the vertical direction, the path of the flow space 11 is connected to the housing 10, And can be deflected downward. In contrast, when the inflow pipe 100 is coupled to the lower side of the housing 10 arranged in the vertical direction and the outflow pipe 200 is coupled to the upper side, the path of the flow space 11 is directed toward the upper side of the housing 10 . At least one impeller (20) is accommodated in the housing (10).

The impeller 20 pressurizes water to move from the inflow pipe 100 to the outflow pipe 200 and is connected to the rotary shaft 32 of the drive motor 30 to be described later and is located in the flow space 11. In other words, the water introduced through the inlet pipe 100 is pressurized by the rotation of at least one impeller 20 located in the flow space 11, and is discharged through the outlet pipe 200. A plurality of impellers 20 may be connected to the rotary shaft 32 in series with each other, and the plurality of impellers 20 may pressurize the water in multiple stages to increase the discharge pressure.

At this time, a plurality of impellers 20 connected in series to the rotary shaft 32 may be respectively accommodated in the impeller receiving portion 11a. The impeller accommodating portion 11a is formed between the impellers 20 and is formed by the partition wall 12 coupled to the inner surface of the housing 10 and may be formed corresponding to the number of the impellers 20. [ Each of the partition walls 12 forming the impeller receiving portion 11a is completely penetrated through the center portion so that the rotating shaft 32 can pass through and a gap can be formed outside the rotating shaft 32 to allow water to flow. That is, the water introduced through the inlet pipe 100 is sequentially pressurized by the impeller 20 accommodated in the respective impeller accommodating portions 11a through the impeller accommodating portion 11a.

The rotating shaft 32 to which the impeller 20 is coupled can receive the rotational driving force from the driving motor 30 and rotate the impeller 20. The drive motor 30 is formed of a main body 31 for generating a driving force and a rotating shaft 32 for transmitting a driving force generated from the main body 31. The main body 31 may be located inside or outside the housing 10. One end of the rotating shaft 32 is connected to the main body 31 and the other end is located inside the housing 10. Hereinafter, a structure in which the main body 31 is located outside the housing 10 will be described more specifically.

The main body 31 is located outside the housing 10 and the rotating shaft 32 has one end connected to the main body 31 and the other end passing through the housing 10 to the inside of the housing 10, 12). Specifically, the main body 31 may be positioned above the support frame 40 coupled to the outer upper surface of the housing 10, and the rotation shaft 32 may penetrate the support frame 40 and the housing 10, (Not shown). Since the first bearing 41 supporting the rotary shaft 32 is disposed outside the rotary shaft 32 passing through the support frame 40, the rotary shaft 32 can rotate smoothly at a predetermined position.

At least one of the housing 10 and the rotary shaft 32 may be provided with a drain hole 10a (see 32a in FIG. 4) to discharge a part of water inside the housing 10. In other words, at least one of the housing 10 and the rotary shaft 32 may be provided with drain holes 10a and 32a passing through the housing 10 or the rotary shaft 32, and the drain holes 10a and 32a A part of the water flowing in the flow space 11 can be discharged to the outside. At this time, the water discharged through the drain holes 10a and 32a may be water containing foreign matter, and the foreign matter may be a nut, a washer, an inclusion or the like. Water containing foreign matter is discharged to the outside through the drain holes 10a and 32a formed in at least one of the housing 10 and the rotary shaft 32 so that the damage of the impeller 20 due to the foreign matter inserted into the pump, So that failure of the pump 1 can be prevented. Particularly, since the conventional operation of stopping the operation of the system and removing the fluid and then separating the pump and the system from each other in order to remove the foreign substances contained in the fluid space 11 is omitted, the overall working efficiency can be improved. Hereinafter, the structure in which the drain hole 10a is formed in the housing 10 will be described more specifically.

The drain holes 10a are formed through the housing 10, and a plurality of drain holes 10a may be spaced apart from each other by a predetermined distance. The plurality of drain holes 10a are disposed along the longitudinal direction of the housing 10 and each drain hole 10a may be positioned in a direction normal to the rotational surface of the impeller 20. [ In other words, the drain hole 10a is located in the normal direction of the rotation surface of the impeller 20, and at least one per impeller receiving portion 11a may be formed. Each of the drain holes 10a is located in the normal direction of the rotating surface of the impeller 20 so that water containing foreign matter and foreign matter is discharged to the drain hole 10a by the centrifugal force due to the rotation of the impeller 20, As shown in Fig. Also, since at least one drain hole 10a is formed for each impeller receiving portion 11a, the impurities contained in each impeller receiving portion 11a can be independently discharged. The circulation pipe 50 may be connected to the drain hole 10a.

The circulation pipe 50 is a pipe for reintroducing the water introduced into the drain hole 10a into the inlet pipe 100. The one end is connected to the drain hole 10a and the other end is connected to the inlet pipe 100. [ One end of the circulation pipe 50 may be branched into a plurality of discharge holes 10a, and the first filter unit 51 may be connected to one side. The first filter unit 51 removes foreign matter flowing into the circulation pipe 50 and may be located on the other end side of the circulation pipe 50 connected to the inflow pipe 100. That is, the water containing the foreign matter flowing into the circulation pipe 50 through the drain hole 10a passes through the first filter unit 51, the foreign matter is removed, and the foreign matter is removed to the inlet pipe 100 Lt; / RTI >

At this time, at least one control valve 52 is formed on the circulation pipe 50 to control the flow of water. The control valve 52 is connected to the housing 10, in particular, to the impeller receiving portion 11a And can be opened and closed in cooperation with the sensor unit 60. The control valve 52 may be formed of, for example, a solenoid valve, and the sensor unit 60 may sense an impact or vibration of a predetermined magnitude or more applied to the impeller receiving portion 11a, for example. Accordingly, when a shock or vibration of a predetermined magnitude or more is sensed by the sensor unit 60, the control valve 52 may open the circulation pipe 50 for a predetermined period of time to remove foreign matter from the impeller accommodation unit 11a .

However, the control valve 52 is not limited to being opened and closed in conjunction with the sensor unit 60, and can be variously modified. For example, the control valve 52 may be opened or closed in conjunction with a flow meter (not shown) or a hydraulic meter (not shown) installed in the inlet pipe 100 or the outlet pipe 200. That is, when the flow rate measured from the flow meter or the hydraulic pressure measured from the hydraulic system deviates from the reference error range, it is determined that the pump 1 is abnormal and the control valve 52 can be opened.

Hereinafter, the operation of the pump 1 will be described in more detail with reference to FIGS. 2 and 3. FIG.

Figs. 2 and 3 are operation diagrams for explaining the operation of the pump of Fig. 1. Fig.

The pump 1 according to an embodiment of the present invention can effectively remove foreign matter existing in the housing 10. [ Therefore, damage of the impeller 20 due to foreign substances present inside the housing 10 and failure of the pump 1 can be prevented, and the service life of the pump 1 can be increased. In addition, since the conventional operation of stopping the operation of the system and removing the fluid and removing the pump and the system in order to remove foreign matter is omitted, the working efficiency can be improved.

Fig. 2 is a view showing the operation of the pump when foreign matter is not detected. Fig.

An inlet pipe (100) is connected to one side of the housing (10) and an outlet pipe (200) is connected to the other side. The housing 10 has a flow space 11 therein and the flow space 11 connects the inlet pipe 100 and the outlet pipe 200 to move the water. An impeller accommodation portion 11a is formed at the center of the flow space 11 by a partition wall 12 coupled to an inner side surface of the housing 10 and an impeller 20 is accommodated in each impeller accommodation portion 11a . A rotating shaft 32 to which a plurality of impellers 20 are coupled in series passes through a central portion of each partition wall 12 and a main body 31 to which the rotating shaft 32 is connected is positioned outside the housing 10. [ A drain hole 10a is formed in one side of each impeller receiving portion 11a and the other end of the circulation pipe 50 having one end connected to the drain hole 10a is connected to the inlet pipe 100. [ The control valve 52 and the first filter unit 51 are formed on the circulation pipe 50 and the control valve 52 is electrically connected to the sensor unit 60 coupled to the outside of the impeller accommodation unit 11a .

The water flowing into the housing 10 through the inlet pipe 100 flows along the flow space 11 and moves to the impeller receiving portion 11a. The water moved to the impeller receiving portion 11a is pressurized by the rotating impeller 20 connected to the rotating shaft 32. The impeller receiving portion 11a and the impeller 20 arranged in series are sequentially passed through the water, do. At this time, when no shock or vibration of a certain magnitude or more is detected from the sensor unit 60 coupled to the outside of the impeller receiving portion 11a, that is, when no foreign matter is detected in the impeller receiving portion 11a, (52) is closed. By closing the control valve 52, the circulation pipe 50 is also closed. The water pressurized by the impeller 20 flows along the flow space 11 and flows out through the outlet pipe 200.

3 is a view showing the operation of the pump when foreign matter is detected.

The water flowing into the housing 10 through the inlet pipe 100 flows along the flow space 11 to the impeller accommodation portion 11a and flows into the impeller accommodation portion 11a through a plurality of impellers (20). At this time, when a shock or vibration of a certain magnitude or more is detected from the sensor unit 60, that is, when foreign matter is detected in the impeller accommodation portion 11a, the control valve 52 is opened. By opening the control valve 52, the circulation pipe 50 is also opened. As the circulation pipe 50 is opened, the water containing the impurities contained in the impeller receiving portion 11a can be introduced into the circulation pipe 50 through the drain hole 10a. Since the drain hole 10a is located in the normal direction of the rotation surface of the impeller 20, water containing foreign matter can be introduced into the drain hole 10a by the centrifugal force due to the rotation of the impeller 20 without any driving force . Further, since the drain hole 10a is formed for each impeller receiving portion 11a, the impurities contained in each impeller receiving portion 11a can be independently removed. The water containing the foreign matter introduced into the circulation pipe 50 passes through the first filter unit 51 and the foreign matter is removed and reintroduced into the inflow pipe 100 in a state where the foreign matter is removed.

On the other hand, water, which is not contained in the water pressurized by the impeller 20, flows along the flow space 11 and flows out through the outlet pipe 200.

Hereinafter, the pump 1 according to another embodiment of the present invention will be described in detail with reference to Figs. 4 to 7. Fig.

FIG. 4 is a view showing a pump according to another embodiment of the present invention, and FIG. 5 is a partially enlarged view of the pump of FIG.

In the pump 1 according to another embodiment of the present invention, the drain hole 32a is formed in the rotary shaft 32. [ The pump 1 according to another embodiment of the present invention is substantially the same as the above embodiment except that a drain hole 32a is formed in the rotary shaft 32. [ Accordingly, the description of the remaining components will be replaced by the foregoing description, unless otherwise noted.

The rotary shaft 32 is formed as a hollow tube and a drain hole 32a is formed on one side and a first drain hole 32b through which the water introduced into the drain hole 32a flows out can be formed on the other side . At this time, the drain hole 32a is formed at a position adjacent to the partition 12 between the impellers 20, and the first outlet hole 32b may be formed outside the impeller receiving portion 11a. In other words, the drain hole 32a is formed to penetrate the rotary shaft 32 and is disposed at a position adjacent to the partition 12 formed between the impellers 20, and the first outlet hole 32b penetrates the rotary shaft 32 And may be disposed outside the impeller receiving portion 11a. The drain hole 32a is formed at a position adjacent to the partition wall 12 so that water containing foreign matter in the water flowing through the center of the partition wall 12 can be introduced into the drain hole 32a. Particularly, since the central portion of the partition wall 12 is narrow and the water pressurized by the rotation of the impeller 20 flows at a high pressure and high pressure, it can flow smoothly into the rotation shaft 32 having a relatively low pressure .

A second filter portion 71 is provided between the drain hole 32a and the first outlet hole 32b and the second filter portion 71 is formed inside the rotary shaft 32 and flows into the rotary shaft 32 Foreign matter can be removed. That is, water flowing into the rotary shaft 32 through the drain hole 32a passes through the second filter unit 71 and is removed, and the foreign matter is discharged through the first outlet hole 32b in a state where the foreign matter is removed. do. As described above, since the first outlet hole 32b is formed outside the impeller receiving portion 11a, the water that flows out to the outside of the rotating shaft 32 through the first outlet hole 32b flows into the impeller receiving portion 11a Lt; / RTI > The water, which is discharged through the first outlet hole 32b, is joined to the water flowing along the flow space 11 and flows out through the outlet pipe 200. [

On the other hand, the drain hole 32a can be opened and closed by the open- The open-close pipe 70 is formed of a hollow pipe and inserted into the inside of the rotary shaft 32, and an opening / closing hole 70a coinciding with the drain hole 32a may be formed. That is, when the drain hole 32a of the rotary shaft 32 is overlapped with the opening / closing hole 70a of the open-close pipe 70, the rotary shaft 32, Water can be introduced into the open-close pipe 70. Conversely, if the drain hole 32a and the open / close hole 70a are shifted from each other, the inflow of water into the open-close pipe 70 can be blocked. At this time, since the first ball check valve 321 is opened in the drain hole 32a and the opening and closing hole 70a in one direction toward the inside of the open-close pipe 70, The water can not flow out to the impeller receiving portion 11a through the drain hole 32a and the opening / closing hole 70a.

Also, the open-close pipe 70 may be formed with a second outflow hole 70b coinciding with the first outflow hole 32b. Therefore, when the drain hole 32a and the opening / closing hole 70a are overlapped, the first outlet hole 32b of the rotary shaft 32 and the second outlet hole 70b of the opening-closing tube 70 are overlapped with each other, Can be discharged into the flow space (11). At this time, since the second ball check valve 322 is formed in the first outlet hole 32b and the second outlet hole 70b and opened in one direction toward the flow space 11, The passing water can not flow into the open-close pipe 70 through the first outlet hole 32b and the second outlet hole 70b. The second filter unit 71 may be installed inside the open-close pipe 70 to remove foreign matter contained in the water flowing inside the open-close pipe 70.

The open-close tube (70) is driven by the open-close tube drive (80). The open-close pipe drive unit 80 may be formed of a hydraulic cylinder or a motor by overlapping the open-close holes 70a with the drain holes 32a or by shifting the open-close holes 70a by rotating or sliding the open-close pipes 70. Hereinafter, a structure in which the open-close pipe drive unit 80 is formed of a hydraulic cylinder will be described more specifically.

The open-close pipe drive unit 80 is interlocked with the sensor unit 60 coupled to the impeller receiving portion 11a and includes a cylinder portion 81, a piston portion 82, and a fluid supply portion 83.

The cylinder portion 81 is located above the main body 31 of the drive motor 30 and accommodates the piston portion 82 therein. One end of the piston portion 82 is connected to the open-close pipe 70 via the connecting rod 72 and is driven inside the cylinder portion 81 to slide the open-close pipe 70 in the vertical direction. The piston portion 82 is driven by the fluid supply portion 83. The fluid supply unit 83 supplies a fluid to the inside of the cylinder unit 81 to drive the piston unit 82 and includes a first fluid supply unit 83a and a second fluid supply unit 83b. The first fluid supply portion 83a supplies the fluid to the upper side of the piston portion 82 and the second fluid supply portion 83b supplies the fluid to the lower side of the piston portion 82. [ Accordingly, when the fluid is supplied to the upper side of the piston portion 82 through the first fluid supply portion 83a, the piston portion 82, the connecting rod 72, and the open-close tube 70 slide downward, The first outlet hole 32a and the opening and closing hole 70a and the first outlet hole 32b and the second outlet hole 70b may be arranged to be shifted from each other. Conversely, when the fluid is supplied to the lower side of the piston portion 82 through the second fluid supply portion 83b, the piston portion 82, the connecting rod 72, and the open-close tube 70 slide upward, The first outlet hole 32a and the second outlet hole 70b may be overlapped with the first outlet hole 32b and the second outlet hole 70b.

However, when the piston portion 82, the connecting rod 72 and the open-close pipe 70 slide downward, the drain hole 32a, the opening and closing hole 70a, and the first outlet hole 32b and the second The present invention is not limited to the arrangement in which the outflow holes 70b are arranged to be shifted from each other and the first outflow hole 32a and the second outflow hole 70b may be deformed depending on the arrangement structure of the drain hole 32a and the opening and closing hole 70a, . For example, when the piston portion 82, the connecting rod 72, and the open-close tube 70 slide downward, the drain hole 32a, the opening / closing hole 70a, and the first outlet hole 32b And the second outlet holes 70b may be arranged to be overlapped with each other.

On the other hand, a protruding portion 70c protruding toward the rotating shaft 32 is formed on the outer side surface of the open-close pipe 70, and an accommodating groove (not shown) formed on the inner side surface of the rotating shaft 32 to accommodate the protruding portion 70c 32c may be formed. At this time, since the receiving groove 32c extends along the longitudinal direction of the open-close pipe 70, the protruding portion 70c is located inside the receiving groove 32c as the open-close pipe 70 slides from the rotary shaft 32 Sliding can be moved. The opening portion 70c is formed in the opening pipe 70 and the receiving groove 32c is formed in the rotating shaft 32 so that the opening pipe 70 is fastened to the rotating shaft 32 to receive the driving force of the main body 31, And can rotate integrally with the rotating shaft 32 which is rotated by the rotating shaft 32. Since the second bearing 73 for supporting the connecting rod 72 is coupled to the outside of the connecting rod 72 for connecting the piston portion 82 and the open-close tube 70, the connecting rod 72 and the open- Can rotate smoothly.

Hereinafter, the operation of the pump 1 will be described in more detail with reference to Figs. 6 and 7. Fig.

6 and 7 are operation diagrams for explaining the operation of the pump of FIG.

First, FIG. 6 is a view showing the operation of the pump when no foreign matter is detected.

The water flowing into the housing 10 through the inlet pipe 100 flows along the flow space 11 and moves to the impeller receiving portion 11a. The water moved to the impeller receiving portion 11a is pressurized by the rotating impeller 20 connected to the rotating shaft 32. The impeller receiving portion 11a and the impeller 20 arranged in series are sequentially passed through the water, do. In this case, when no shock or vibration of a certain magnitude or more is detected from the sensor unit 60 coupled to the outside of the impeller receiving portion 11a, that is, when no foreign matter is detected in the impeller receiving portion 11a, The fluid is supplied into the cylinder portion 81 through the fluid supply portion 83a and the fluid is discharged to the outside of the cylinder portion 81 through the second fluid supply portion 83b. The piston portion 82 accommodated in the cylinder portion 81 and the connecting rod 72 and the open-close tube 70 slide downward by the fluid being supplied through the first fluid supply portion 83a, The hole 32a and the opening and closing hole 70a and the first outlet hole 32b and the second outlet hole 70b are arranged to be shifted from each other. Accordingly, the inflow of water into the open-close pipe 70 is blocked, and the water pressurized by the impeller 20 flows along the flow space 11 and flows out through the outflow pipe 200.

7 is a view showing the operation of the pump when foreign matter is detected.

The water introduced into the housing 10 flows along the flow space 11 and moves to the impeller receiving portion 11a and is connected to the rotating shaft 32 by a plurality of impellers 20, Lt; / RTI > In this case, when an impact or vibration of a certain magnitude or more is detected from the sensor unit 60, that is, when foreign matter is detected in the impeller receiving unit 11a, the inside of the cylinder unit 81 through the second fluid supply unit 83b And the fluid is discharged to the outside of the cylinder portion 81 through the first fluid supply portion 83a. The piston portion 82, the connecting rod 72 and the open-close tube 70 slide upward while the fluid is supplied through the second fluid supply portion 83b. As a result, the drain hole 32a and the opening / And the first outlet hole 32b and the second outlet hole 70b are overlapped with each other. Therefore, water containing foreign matter can be introduced into the open-close pipe 70 through the drain hole 32a and the open / close hole 70a. Since the drain hole 32a is formed at a position adjacent to the partition wall 12, water flowing at a high speed and high pressure through the center of the partition wall can flow smoothly into the open-close pipe 70 having a relatively low pressure.

The water containing the foreign matter introduced into the open pipe 70 flows through the second filter unit 71 and the foreign matter is removed and the second outlet hole 70b and the first outlet hole 32b (Not shown). The first outlet hole 32b is formed outside the impeller receiving portion 11a so that the water from which the foreign matter discharged into the flow space 11 is removed does not flow into the impeller receiving portion 11a and flows into the flow space 11, And then flows out through the outflow pipe 200. [0050]

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You will understand. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1: pump 10: housing
10a: drain hole 11: floating space
11a: impeller housing part 12: partition wall
20: impeller 30: drive motor
31: main body 32:
32a: drain hole 32b: first outlet hole
32c: receiving groove 321: first ball check valve
322: second ball check valve 40: support frame
41: first bearing 50: circulation pipe
51: first filter section 52: control valve
60: sensor unit 70: open-close
70a: opening / closing hole 70b: second outlet hole
70c: protruding portion 71: second filter portion
72: connecting rod 73: second bearing
80: open-close pipe drive part 81: cylinder part
82: piston part 83: fluid supply part
83a: first fluid supply part 83b: second fluid supply part
100: inlet pipe 200: outlet pipe

Claims (8)

A housing connected to an inlet pipe through which water flows into the one side and to an outlet pipe through which the water flows out from the other side; And
And a plurality of impellers connected to the rotating shaft and received in the housing, for moving the water from the inlet pipe to the outlet pipe,
Wherein a drain hole is formed in at least one of the housing and the rotary shaft. The circulation pipe according to claim 1, wherein one end portion is connected to the drain hole and the other end portion is connected to the inflow pipe; And
And a first filter unit connected to the circulation pipe to remove foreign matter. The pump according to claim 2, wherein the drain hole is located in a direction normal to the rotating surface of the impeller. The pump according to claim 1, wherein a partition wall is provided between the plurality of impellers to form a plurality of impeller receiving portions, and the drain holes are located in at least one of the plurality of impeller receiving portions. The pump according to claim 1, wherein the rotation shaft is formed as a hollow pipe, the drain hole is formed on one side, and the outflow hole is formed on the other side. 6. The pump according to claim 5, wherein a partition wall is provided between the plurality of impellers to form a plurality of impeller receiving portions, the drain holes are located adjacent to the partition, and the outlet holes are formed outside the impeller receiving portion. [6] The apparatus of claim 5, further comprising: a hollow open-close pipe inserted into the rotation shaft and having an opening / closing hole coinciding with the drain hole; And
Closing pump, wherein the opening-closing hole is rotated or slidably moved so that the opening-closing hole is overlapped with or displaced from the drain hole. The pump according to claim 5, further comprising a second filter unit formed inside the rotating shaft to remove foreign matter flowing into the rotating shaft.

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