KR101019856B1 - Rotational strainer of vertical sump pump and vertical sump pump having the same - Google Patents

Abstract

PURPOSE: A rotational strainer of a vertical sump pump and a vertical sump pump having the same are provided to reduce the overloading of a motor and energy loss and prevent damage to impeller, thereby expanding service life of a pump. CONSTITUTION: A rotational strainer of a vertical sump pump comprises a fixed strainer(20) and a rotary strainer(10). The fixed strainer is fixed to the casing of the bottom of a pump. The rotary strainer is installed inside the fixed strainer with being separated from the fixed strainer. The rotary strainer is connected to the impeller shaft of the pump. The rotary strainer rotates along the rotation of the impeller. Foreign materials, flowing in from the outside of the pump, are crushed between the fixed strainer and the rotary strainer by the rotation of the rotary strainer.

Description

ROTATIONAL STRAINER OF VERTICAL SUMP PUMP AND VERTICAL SUMP PUMP HAVING THE SAME

The present invention relates to a strainer that is installed to surround the suction part of the vertical centrifugal pump to filter foreign substances introduced into the pump from the outside, and more particularly, to a rotary strainer capable of filtering as well as crushing the foreign substances.

The present invention also relates to a vertical centrifugal pump having the rotary strainer.

The vertical centrifugal pump is a pump that sucks water through the suction port and pumps it to the discharge pipe by the rotary centrifugal action of the impeller rotated by the motor, and pumps groundwater or wastewater in various industrial sites such as construction sites or wastewater treatment facilities. It is an industrial pump used for.

 The water suction part of the bottom of the vertical centrifugal pump is provided with a strainer for filtering foreign matter contained in the pumped water.

1 is a view showing a vertical centrifugal pump provided with a conventional strainer at a pump lower end portion.

As shown in FIG. 1, a strainer 8 made of a mesh or a metal plate having a plurality of filter holes is fixedly coupled to the vertical centrifugal pump lower casing 5.

When the motor shaft (2) is rotated by operating the motor (1) installed on the upper part of the pump, the impeller shaft (3) and the impeller (4) connected thereto rotate, and water is discharged by the rotary centrifugal action of the impeller (4). Passed through the strainer (8) is sucked into the pump inlet (6) and pumped to the discharge pipe (7). In this process, foreign matter contained in the water is selectively filtered by the filtration holes (not shown) of the strainer 8, the strainer 8 is to achieve a filtration function.

However, such a conventional strainer 8 has a disadvantage in that when the waste water containing various foreign substances such as sludge, garbage, vinyl, etc. is pumped up, foreign substances of various sizes block the holes of the strainer. In particular, foreign matters below the diameter of the filtration holes are introduced into the impeller through the filtration holes, and this foreign matter has a problem of damaging the impeller rotating at high speed. In addition, when the foreign matter is centrifugally rotated together with the sewage, motor energy is unnecessarily lost and causes overload of the motor. In addition, when the foreign matter is mixed up to the discharge pipe, the flow rate as much as the foreign matter does not spread, it is difficult to achieve the pumping capacity according to the design value, there is a problem in that it is difficult to control the flow rate.

The present invention is to solve the above-mentioned conventional problems, by greatly reducing the size of the foreign matter flowing into the pump by rotating crushed foreign matter, to prevent the filter hole of the strainer to be blocked, and to prevent damage to the motor and impeller To provide a strainer of a vertical centrifugal pump.

In addition, another object of the present invention is to provide a strainer of a vertical centrifugal pump capable of filtration of foreign matters in double or triple.

It is another object of the present invention to provide a vertical centrifugal pump capable of effectively pumping the pump by providing the strainer.

In order to achieve the above object, the strainer of the vertical centrifugal pump of the present invention, the strainer is installed to surround the suction portion of the vertical centrifugal pump to filter foreign substances flowing into the pump from the outside, the fixed fixed to the casing of the lower end of the pump A strainer and a rotating strainer installed in the fixed strainer at intervals with the fixed strainer and connected to the impeller shaft of the pump to rotate in accordance with the rotation of the impeller, wherein foreign substances introduced from the outside of the pump It is characterized in that the grinding between the fixed strainer and the rotary strainer by the rotation of the rotary strainer.

In addition, the rotary strainer of the present invention, the rotary strainer is composed of a cylindrical strainer body formed with a plurality of filtration holes, the upper and lower portions are open, and a bottom plate coupled to the lower portion of the main body, one end is fastened to the impeller shaft It is preferable that the other end of the bolt is fixed to the bottom plate.

In addition, the rotary strainer of the present invention, the fixed strainer, a cylindrical strainer body having a plurality of filtration holes are formed and the upper and lower portions are opened, an upper flange coupled to the upper end of the strainer body, and a bottom plate coupled to the bottom of the strainer body In one embodiment, the upper flange is fixed to the casing of the lower end of the pump.

In addition, the rotary strainer of the present invention preferably further includes an outer strainer that surrounds the outside of the fixed strainer and is fixedly coupled to the casing of the pump lower end.

In addition, the rotary strainer of the present invention, the outer strainer, a cylindrical strainer body having a plurality of filtration holes are formed and the upper and lower portions are opened, an upper flange coupled to the upper end of the strainer body, and a bottom plate coupled to the bottom of the strainer body It is preferred that the upper flange is secured to the casing of the pump lower end.

Further, in the rotary strainer of another preferred embodiment of the present invention, a recess is formed along the circumferential direction on the surface portion adjacent to the inner circumference of the upper flange upper surface of the outer strainer, and the upper flange of the fixed strainer is placed on the recess. The strainer is fixedly coupled to the casing of the lower end of the pump, so that the upper flange of the fixed strainer is fitted to the concave surface of the pump lower end casing of the upper surface and the outer strainer upper flange of the lower surface thereof.

On the other hand, this invention also makes the object the vertical centrifugal pump provided with the rotary strainer in any one of the said Example.

According to the present invention, it is possible to greatly reduce the amount of foreign matter introduced into the pump by pulverizing the foreign matter by using the rotational force of the motor and the impeller without a separate strainer rotating mechanism.

In addition, since only the foreign matter of a small size is introduced into the pump by crushing the foreign matter, it is possible to reduce the motor overload and energy loss, to prevent impeller damage to achieve the effect of extending the pump life.

In addition, the clogging of the strainer's filtration holes due to the micronization of the foreign matter is also greatly reduced, and the flow of water flow due to the foreign matter is reduced, so that the flow rate can be easily controlled and the pumping capacity to the design value can be kept constant.

In addition, according to the present invention, it is possible to filter the foreign matter in multiple, there is an effect that the filtration function itself is improved.

1 is a view showing a vertical centrifugal pump provided with a conventional strainer at a pump lower end portion.
2 is an overall schematic view of a vertical centrifugal pump provided with the rotary strainer of the present invention.
3 is a cross-sectional view of the rotary strainer of the present invention installed in the suction portion of the vertical centrifugal pump.
4 is a schematic view of a rotary strainer which is one component of the rotary strainer of the present invention.
5 is a schematic diagram of a stationary strainer that is one component of the rotary strainer of the present invention.
6 is a schematic view of an external strainer which is another component of the rotary strainer of the present invention.

Hereinafter, with reference to the drawings will be described a preferred embodiment of the present invention.

2 is an overall schematic view of the vertical centrifugal pump 100 provided with the rotary strainer S of the present invention, and FIG. 3 is the rotary strainer S of the present invention installed in the suction part (pump bottom) of the vertical centrifugal pump 100. ) Is a cross-sectional view.

As shown in Figure 2 and 3, the rotary strainer (S) of the present invention, the fixed strainer 20 is fixed to the casing 140 of the lower end of the vertical centrifugal pump 100, and the fixed strainer 20 It is essentially provided with a rotary strainer 10 installed at intervals therein, the rotary strainer 10 is connected to the impeller shaft 131 of the pump 100 together with the rotation of the impeller 130 It is configured to rotate.

The most distinctive feature of the rotary strainer S of the present invention, which is distinguished from the conventional strainer, is that it is equipped with a function capable of pulverizing foreign matters by rotational force in addition to the filtration function of simply filtering foreign matters. That is, the present invention is to improve the filtration function by installing a double strainer (fixed strainer 20 and the rotary strainer 10), as well as the motor 110 and the mandatory essentially provided in the pump 100 in particular The greatest feature is that the rotational grinding function is applied to the strainer S using the rotational force of the parlor 130.

The reason that the foreign matter is crushed is because the rotary strainer 10 and the fixed strainer 20 act like a double blade of scissors. The rotary strainer 10 and the fixed strainer 20 are each a metal plate (perforated metal plate) or a net formed with a plurality of filter holes 12a and 22a (only a part of the filter holes are shown for convenience of description, hereinafter identical). The hole edges of the two strainer filtration holes 12a and 22a or the metal plate portion opposite thereto act like a blade of scissors to cut and grind foreign matter flowing between the strainers. The rotary strainer 10 rotates at a high speed by the rotational force of the motor 110, and the rotary strainer 10 performs the same function as the cutter, thereby rotating and grinding the foreign matter together with the fixed strainer 20 opposite thereto. In general, the motor of the granular centrifugal pump rotates at a high speed of 350 to 1500 rpm, so that the rotary strainer 10 also rotates at the same rpm at high speed, and the high-speed rotational force can facilitate rotational grinding of the foreign matter. If the rotary strainer 10 can be rotatably coupled with the impeller shaft 131, the connection or coupling method of the rotary strainer 10 and the impeller shaft 131 may be any method.

 Figure 4 is a schematic diagram of a rotary strainer 10 which is one component of the rotary strainer S of the present invention, showing an embodiment of a combination of the rotary strainer 10 and the impeller shaft 131.

In this embodiment, the rotary strainer 10 is composed of a cylindrical strainer main body 12 having a plurality of filter holes 12a and the upper and lower portions are opened, and a bottom plate 13 coupled to the lower part of the main body. have. The strainer main body 12 can be produced by rolling a perforated plate metal or net in a cylindrical shape and welding both ends. The bottom plate 13 may be coupled to the lower portion of the strainer body 12 by welding. In this embodiment, one end is coupled to the bottom plate 13 of the rotational strainer 10 by coupling the other end of the computer bolt B fastened to the impeller shaft 131, thereby using a rotational strainer (B). 10) is connected to the impeller shaft (131). Of course, the end of the impeller shaft 131 is directly extended to be coupled to the bottom plate 13 of the rotary strainer 10, or the rotary strainer 10 is coupled to the impeller shaft 131 using another fastening member. It can also be assumed. However, since the extension of the impeller shaft 131 itself may be disadvantageous in terms of machining surface and manufacturing cost, it is preferable to use a member that is easy to machine and fasten, such as the computer bolt B. For example, a tapping process is formed to form a screw hole at the end of the impactor shaft 131, and the threaded bolt B is fastened to the hole, and the other end of the threaded bolt B is welded to the bottom plate of the rotary strainer 10, or By means of bolt-nut fastening, the rotating strainer 10 can be easily and simply fixed to the impeller shaft 131 through the computer bolt B.

5 is a schematic view of a fixed strainer 20, which is a component of the rotary strainer S of the present invention, wherein the fixed strainer 20 has a cylindrical shape in which a plurality of filter holes 22a are formed and the upper and lower portions thereof are opened. It consists of a strainer body 22, an upper flange 21 coupled to the upper end of the strainer body 22, and a bottom plate 23 coupled to the lower end of the strainer body 22. The stationary strainer 20 is fixed to the pump lower casing 140 to serve as a stationary blade opposed to the rotating rotary strainer 10. The fixed strainer 20 may fix the upper flange 23 to the casing 140 at the lower end of the pump by a fastening member such as a bolt-nut. Alternatively, as described below, there is also a method of indirectly fixing the fixed strainer 20 to the pump casing 140 by using the fastening force of the external strainer 30.

FIG. 6 is a schematic diagram illustrating an outer strainer 30 that wraps around the outside of the fixed strainer 20 and is fixedly coupled to the casing 140 at the bottom of the pump as another embodiment of the present invention. The outer strainer 30 performs a function of primarily filtering foreign matter from the outside of the fixed and rotary strainer 10. Since there is a limit to the size of the foreign matter that is rotationally crushed by the fixed-rotating strainer 20, 10, by installing the external strainer 30, only the foreign matter of the crushable size is introduced into the fixed-rotating strainer 20, 10 side. You can do it.

The structure of the outer strainer 30 is similar to the structure of the fixed strainer 20, a plurality of filter holes (32a) is formed and the upper and lower cylindrical strainer body 32 is open, coupled to the top of the strainer body 32 It consists of the upper flange 31 and the bottom plate 33 is coupled to the lower end of the strainer body (32). However, the upper flange 31 preferably has a larger diameter and thickness than the upper flange 21 of the fixed strainer 20, and the upper flange 31 is fixedly coupled to the casing 140 of the pump lower end. .

Coupling the outer strainer 30 and the fixed strainer 20 to the casing 140 by separate fastening members, respectively, complicates the device and unnecessarily increases the manufacturing process. In FIG. 3, the fastening member is used only for the outer strainer 30, and the fixed strainer 20 is indirectly fixed by the fastening force of the fastening member.

In this embodiment, a concave portion 31R is formed along the circumferential direction in a surface portion adjacent to the inner circumference of the upper surface of the upper flange 31 of the outer strainer 30, and the fixed strainer 20 is formed in the concave portion 31R. The upper flange 21 of is placed. At this time, the upper surface of the upper flange 21 of the fixed strainer 20 is in contact with the lower surface of the casing 140, and the lower surface of the upper flange 21 is on the surface of the upper flange recess 31R of the outer strainer 30. It is supported. The outer strainer 30 is formed by the fastening members H and C in the casing 140 of the recess 31R outer portion of the outer strainer 30 and the casing 140 of the pump lower portion opposite thereto. Is fixed to the casing 140, the upper flange 21 of the fixed strainer 20 is fitted to the upper flange 31 of the upper pump lower casing 140 and the lower outer strainer 30 to be naturally fixed. do. Therefore, it is not necessary to use a separate fastening member for fixing the fixed strainer 20. In addition, if the thickness of the upper strainer 20 of the fixed strainer 20 is slightly larger than the depth of the recess 31R, when the outer strainer 30 is fixedly coupled, the upper flange of the fixed strainer 20 ( 21 may be tightly fitted between the pump casing 140 and the outer strainer 30 to be more firmly fixed to the pump casing 140.

As shown in FIG. 2, the lower portion of the pump 100 is provided with an external strainer 30, a fixed strainer 20, and a rotary strainer 10, which are one embodiment of the present invention, and the rotary strainer 10. It is fixedly coupled to the impeller shaft 131 installed in the pump lower casing 140 by a computer bolt (B). The motor 110 is installed in the upper part of the pump, and the pump shaft shaft 121 is coaxially fixed to the motor 110 shaft in the column pipe 120 at the pump middle part. The other end of the pump shaft shaft 121 is coupled to the impeller shaft 131 of the impeller 130. Of course, the pump shaft shaft 121 and the impeller shaft 131 may be integrally formed as one shaft shaft.

2, the operation of the present invention will be described in detail.

When the pump operation switch is turned on, the motor 110 installed above the vertical centrifugal pump 100 and the motor 110 connected thereto, the shaft-pump shaft shaft 121, and the impeller shaft 131 rotate together. The parlor 130 rotates to suck water into the pump 100 by the rotation centrifugal action, and the sucked water is discharged to the upper portion of the pump 100 through the discharge pipe 150.

At this time, the foreign matter contained in the water is primarily filtered by the outer strainer 30, and secondly by the fixed strainer 20 of the inner side. Fine foreign matters, which are introduced into the gap between the fixed strainer 20 and the rotary strainer 10 through the fixed strainer 20, are sucked into the pump 100 through the filtration holes 12a of the rotary strainer 10. do. However, foreign matters of a diameter larger or similar to the filtration holes 12a of the rotary strainer 10 are crushed by the rotary strainer 10 connected to the impeller shaft 131. The edge portion of the strainer main body 12 and the filtration hole 12a of the rotary strainer 10 functions as a rotary blade to perform a function of cutting a foreign material, and the main body 22 and the filtration hole of the fixed strainer 20 opposite thereto. The edge part of 22a acts as a fixed blade, and foreign materials are cut and pulverized like scissors. Since the rotary strainer 10 rotates at high speed together with the impeller 130, there is no need for a separate drive mechanism or a power mechanism for separately rotating only the rotary strainer 10. In addition, since the impeller 130 rotates at a very high speed of 350 to 1500 rpm, foreign substances introduced at intervals between the fixed-rotating strainers 20 and 10 are instantly pulverized in a very short time.

Due to such a grinding action, since only the foreign matter having a small size pulverized into the rotary strainer 10 is smaller than or equal to the size of the filtration hole 12a, usually much smaller than the size, the impeller 130 or the high speed rotating Since the impact amount on the motor 110 is also greatly reduced, not only the impeller 130 can be prevented from being damaged, but the overload of the motor 110 can be prevented, and the energy of the motor 110 is caused by foreign matter. Unnecessary waste can be greatly reduced. In addition, because foreign matter is crushed finely. The phenomenon that the foreign material blocks the filtration hole 12a of the rotary strainer 10 is also significantly reduced.

Moreover, foreign matters of the water flowing into the discharge pipe 150 become extremely fine, and since the foreign matters having a large particle diameter are hardly introduced into the pump 100, the inflow rate of the foreign matters in the pump 100 is greatly reduced, and according to the design value. Pumping capacity can be kept constant. In addition, since the flow of water suction-discharged in the pump 100 becomes smooth without being disturbed by foreign substances, the flow rate control of the pump 100 is also very easy.

In addition, when the rotary strainer S is installed in the vertical centrifugal pump 100, damage to the impeller 130 or the motor 110 can be prevented, and thus the life of the pump 100 can be extended. A great effect can also be seen in improving the pump 100 efficiency.

On the other hand, the interval between the rotary strainer 10 and the fixed strainer 20 is determined within the most preferred range for the crushing of foreign matter. If the interval is too close or too far, the grinding function of the foreign matter may be reduced or the resistance at the time of grinding the foreign matter may be too large. Therefore, it is necessary to determine the distance between both strainers in the range where the foreign matter grinding efficiency is optimized.

In addition, the size of the filtration hole 22a of the fixed strainer 20 is preferably equal to or larger than the size of the rotary strainer 10 filtration hole 12a. By reducing the size of the rotary strainer 10 filter hole 12a, foreign substances passing through the fixed strainer 20 and the rotary strainer 10 may be sequentially filtered according to the size. In addition, even if both strainer filtration holes 12a and 22a have the same size, foreign matter is finely pulverized at intervals between both strainers 10 and 20, so that foreign matter may block the rotary strainer 10 filtration hole 12a. Since it is greatly reduced, even if the size of the rotary strainer 10 filter hole (12a) to the same as the fixed strainer 20, there is no major problem in the filtration function.

When the outer strainer 30 is provided outside the fixed strainer 20, the size of the filtration hole 32a needs to be larger than that of the fixed strainer 20 filtration hole 22a. The outer strainer 30 does not contribute to the rotary grinding function of the present invention, but by filtering large foreign materials, the external strainer 30 functions to help effectively grind the foreign materials in the fixed-rotating strainer 20, 10 intervals. .

The material of each strainer can use a metal plate, resin, and other various materials. However, at least the fixed strainer 20 and the rotary strainer 10 may have a strength capable of rotating and grinding the foreign matter and withstanding the rotational grinding resistance. For example, by using a stainless steel plate having a large number of filtration holes, it is possible not only to prevent corrosion by water or foreign matters, but also to easily rotate and grind the foreign matters.

The present invention is not limited in scope by the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention described in the claims. For example, embodiments using the outer strainer 30 as a fixed strainer are also possible. That is, in FIG. 3, the fixed strainer 20 between the external strainer 30 and the rotary strainer 10 is removed and the external strainer 30 is used as the fixed strainer 20 to form the rotary strainer 10 as the external strainer ( The invention which rotates about 30 can also fully achieve the rotary grinding effect of this invention. In addition, the outer strainer 30, the fixed strainer 20 fixed to the pump casing 140, the coupling method of the rotary strainer 10 to the impeller shaft 131, any modification within the scope of the technical common knowledge of those skilled in the art. This is possible.

100 ... Vertical Centrifugal Pump 110 ... Motor
120 ... column pipe 121 ... pump shaft
130 ... impeller 131 ... impeller shaft
140 ... pump lower casing 150 ... discharge line
S ... rotary strainer 10 ... rotary strainer
12 ... rotary strainer body 12a ... filtration hole
13 ... bottom plate 20 ... fixed strainer
21 ... upper flange 22 ... fixed strainer body
22a ... filter 23 ... bottom plate
30 ... outer strainer 31 ... upper flange
31 R ... recess 32 ... fixed strainer body
H ... Fastener 32a ... Filtration
33 ... Bottom plate B ... Computer bolt

Claims (7)

In the strainer is installed to surround the suction part of the vertical centrifugal pump to filter foreign matter flowing into the pump from the outside,
A fixed strainer fixed to the casing of the lower end of the pump,
It is installed in the fixed strainer spaced apart from the fixed strainer, and comprises a rotary strainer connected to the impeller shaft of the pump to rotate in accordance with the rotation of the impeller,
Foreign matter flowing from the outside of the pump is pulverized between the fixed strainer and the rotary strainer by the rotation of the rotary strainer,
Rotating strainer of the centrifugal pump further comprises an outer strainer surrounding the outside of the fixed strainer and fixedly coupled to the casing of the lower end of the pump. The method of claim 1,
The rotary strainer is composed of a cylindrical strainer body formed with a plurality of filter holes and the upper and lower portions are opened, and a bottom plate coupled to the lower portion of the main body,
Rotary strainer of the vertical centrifugal pump, characterized in that the other end of the computer bolt is fixed to the bottom plate one end is fastened to the impeller shaft. The method of claim 2,
The fixed strainer is formed of a cylindrical strainer body having a plurality of filtration holes and an open upper and lower portions, an upper flange coupled to an upper end of the strainer body, and a bottom plate coupled to a lower end of the strainer body,
Rotary strainer of a vertical centrifugal pump wherein the upper flange is secured to a casing at the bottom of the pump. delete The method of claim 1,
The outer strainer is composed of a cylindrical strainer body having a plurality of filtration holes and an open upper and lower portions, an upper flange coupled to an upper end of the strainer body, and a bottom plate coupled to a lower end of the strainer body,
Rotary strainer of a vertical centrifugal pump wherein the upper flange is secured to a casing at the bottom of the pump. The method of claim 5, wherein
A recess is formed along the circumference of the surface portion adjacent to the inner circumference of the upper surface of the upper flange of the outer strainer,
The upper flange of the fixed strainer is placed in the recess
The outer strainer is fixedly coupled to the casing of the lower end of the pump, so that the upper flange of the fixed strainer is fitted to the concave surface of the lower end casing of the upper end of the pump and the upper flange of the outer strainer of the lower side. Rotary strainer of vertical centrifugal pump. The vertical centrifugal pump provided with the rotary strainer as described in any one of Claims 1-3, 5.

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