KR101743024B1 - Submersible pump with perforated plate - Google Patents

Abstract

The present invention relates to a submersible pump, and more particularly, to a submersible pump which effectively separates foreign matter introduced together with sewage, and further, presses the foreign matter to one side to secure a space through which sewage can flow smoothly, To thereby improve the cutting efficiency and the flow efficiency of the sewage, and a submerged pump including the perforated plate.
The present invention is characterized in that an underwater pump for pumping sewage containing foreign matter from an inlet 11 to an outlet 12 by an impeller 15 which receives rotational force of a pump motor 13 via a rotary shaft 14 A perforated plate 30 coupled to the inlet 11 side and forming a plurality of holes to pass foreign matter and sewage; And a cutting blade 20 coupled to the tip of the perforated plate 30 for cutting foreign materials while rotating. The perforated plate 30 includes a shaft hole 31 through which the rotating shaft 14 passes; A bolt hole (32) for fixing to the underwater pump body; And a flow induction cutting hole 33 through which the sewage flows together with the foreign matter, and the flow inducing cutting hole 33 is formed by a compression inducing area 43 (a region corresponding to a radius range of the cutting blade 20) ); And a foreign matter free flow region (hereinafter referred to as a " foreign matter free flow region "), which is a region through which the foreign matter and the sewage pass without contact with the cutting blade 20, 41).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a submersible pump having a perforated plate for a submersible pump,

The present invention relates to a submersible pump, and more particularly, to a submersible pump which effectively separates foreign matter introduced together with sewage, and further, presses the foreign matter to one side to secure a space through which sewage can flow smoothly, To thereby improve the cutting efficiency and the flow efficiency of the sewage, and a submerged pump including the perforated plate.

In general, submersible pumps for sewage are used in sewage treatment facilities. In other words, submerged pumps are used to transfer the sewage that is generated in the sewage treatment area to the front side of the sewage treatment facility through the secondary pipeline to the general sewage treatment system.

That is, the underwater pump for the inflow pump of the sewage treatment plant is blocked by the overload of the motor due to the decrease of the discharge amount because the impurities block the front end perforation plate of the impeller.

Therefore, it is decomposed and cleaned from time to time to solve impeller shear clogging, so that the operation of the pump is smooth.

This clogging causes the operation rate to be low and the work efficiency to decrease. In addition, these cutting edges often replace the grinder blades, wasting budget.

Therefore, a technical proposal of a submersible pump to compensate for this is desperately required.

Registration Practical Utility Model No. 20-0262714 (Announcement on Mar. 18, 2002) Open Patent No. 10-2009-0113589 (published on November 02, 2009) Registered Patent No. 10-1497052 (Announcement on Feb. 27, 2015)

In order to solve the above-described problems, the present invention provides a submerged pump for pumping sewage, which is provided with a cutting blade and a perforated plate, wherein a portion of the flow- The main purpose of this system is to improve the efficiency of submersible pump operation by preventing the clogging phenomenon by smoothly transporting the sewage, increasing the flow rate of the sewage and increasing the flow rate of the sewage.

Another object of the present invention is to allow the cutting blade to densely flow the sewage into the space where the foreign matter is removed by densifying the foreign matter to one side.

It is another object of the present invention to improve the cutting efficiency by cutting foreign matter while crossing along a sloping line by a cutting blade.

In order to achieve the above object, according to the present invention, the impeller (15) that receives the rotational force of the pump motor (13) through the rotary shaft (14) (30) coupled to the inlet (11) side and forming a plurality of holes to allow foreign matter and sewage to pass therethrough; And a cutting blade 20 coupled to the tip of the perforated plate 30 for cutting foreign materials while rotating. The perforated plate 30 includes a shaft hole 31 through which the rotating shaft 14 passes; A bolt hole (32) for fixing to the underwater pump body; And a flow induction cutting hole 33 through which the sewage flows together with the foreign matter, and the flow inducing cutting hole 33 is formed by a compression inducing area 43 (a region corresponding to a radius range of the cutting blade 20) ); And a foreign matter free flow region (hereinafter referred to as a " foreign matter free flow region "), which is a region through which the foreign matter and the sewage pass without contact with the cutting blade 20, 41). The submersible pump (1) according to any one of claims 1 to 3,

In the preferred embodiment of the present invention, the flow-induced cutting hole 33 is formed in such a manner that the foreign matter introduced into the squeeze induction area 43 abuts on the inwardly sloping sloping sloping line 56, A dense induction cut region 45 which is pressed and cut by being pushed in an oblique direction of the cut-off induction cut region 45; The cutting edge 20 and the cutting corner line 57 can be prevented from being rotated by the cutting corner line 57 which is the end of the flow inducing cutting hole 33 with respect to the rotating direction of the cutting blade 20, And a cutting area (47) which is a region of the tip end of the cutting corner line (57).

In the preferred embodiment of the present invention, the flow-induced cutting hole 33 is formed in a shape of a circular arc shape having a large radius as the cutting edge 20, A leading inflow curve line 51; An induction inner line (52) extending from the inward direction end of the leading inflow curve line (51) and forming a boundary between the flow induction cutting hole (33) and the shaft hole (31) direction; A flow outer line 53 extending from the outward direction end of the leading inflow curve line 51 and forming an outward boundary with the flow inducing cutter 33; A flow conversion line 54 connected to the flow outer line 53 and forming an arcuate continuity with the other of the inclined flow pressure gradient line 55 at the end of the free flow region 41; A sloping flow pressure ramp line 55 bounding the flow diversion line 54 and bounding the end of the foreign material free flow region 41; A foreign matter in the compression induction area 43 is densely packed in the dense induction cut area 45 by the cutting blade 20 and the inclined trimming cut oblique line 45 is cut at the intersection with the cutting blade 20 while pressing the foreign matter in the oblique direction. (56); A cutting corner line 57 forming a boundary of an end portion of the rotating cutting blade 20 in the rotational direction and cutting an object at an intersection with the cutting blade 20 in the cutting area 47; And a cutting inner slanting line (58) inclined in a direction opposite to the slanting slanting line (56) and cutting the foreign matter of the cutting area (47) while pressing it in a slanting direction. Lt; / RTI >

The angle d between the direction in which the flow pressure slanting line 55 and the trimming cutting slanting line 56 are directed with respect to the direction of the flow of the foreign material free flowing region 41 is 100 to < RTI ID = 0.0 > And the width of the compression inducing area 43 is in the range of 3.2 to 8.9 times the width of the dense induction cut area 45 and the cut area 47. [ Thereby providing a submersible pump.

In the preferred embodiment of the present invention, in the above-described submerged pneumatic pump, the rotational force of the pump motor 13 is transmitted from the inlet 11 to the outlet 12 by the impeller 15, A plurality of holes are formed so as to allow foreign matter and sewage to flow and to cut foreign substances at intersections with the cutting blade 20 provided together, A shaft hole 31 through which the shaft 14 passes; A bolt hole (32) for fixing to the underwater pump body; And a flow induction cutting hole 33 through which the sewage flows together with the foreign matter, and the flow inducing cutting hole 33 is formed by a compression inducing area 43 (a region corresponding to a radius range of the cutting blade 20) ); And a foreign matter free flow region (hereinafter referred to as a " foreign matter free flow region "), which is a region through which the foreign matter and the sewage pass without contact with the cutting blade 20, 41). The present invention provides a submerged pier for a submersible pump.

According to the present invention configured as described above, the perforated pump for pumping sewage is provided with a perforated plate together with a cutting blade. The perforated plate has a region where a cutting blade is not formed at one side of the flow induction cutting hole through which sewage flows, The flow of sewage can be smoothly increased, the flow rate can be increased, and the clogging phenomenon can be prevented, thereby increasing the efficiency of underwater pump operation.

Further, another effect of the present invention is that the cutting blade always flows the sewage into the space where the foreign matter is removed by densifying the foreign matter to one side.

Yet another effect of the present invention is to cut the foreign matter while crossing the inclined line by the cutting blade to improve the cutting efficiency.

Further, since the foreign matter is pressed by the cutting blade and then cut, the foreign matter is densely packed to a predetermined degree, and the cutting is performed well.

1 is an exploded perspective view of a submersible pump with a perforated plate according to the present invention.
2 is a perspective view of a perforated plate according to the present invention.
3 is a front view of a perforated plate according to the present invention.
FIG. 4 is a sectional view showing an induction region and a cut region of a foreign substance in the perforated plate according to the present invention.
5 is an exemplary view for explaining an angular range occupied by a plurality of divided regions in the perforated plate according to the present invention.
FIG. 6 is an exemplary view for explaining a region where a foreign substance is induced and squeezed and cut in a perforated plate according to an embodiment of the present invention, and a region where a foreign substance flows freely.
FIG. 7 is an explanatory view illustrating details of edges of a flow-induced cutting hole through which foreign matters and sewage pass in the perforated plate according to the present invention.
FIG. 8 is an explanatory diagram illustrating a state in which a cutting edge of a perforated plate according to an embodiment of the present invention passes a leading end portion of a flow inducing cutting hole.
FIG. 9 is an explanatory diagram illustrating a state in which a cutting edge of a piercing plate according to the present invention passes through a middle portion of a compression inducing area in a flow-induced cutting hole.
FIG. 10 is an explanatory diagram illustrating a state in which a cutting blade of a piercing plate according to the present invention densifies foreign matter passing through a rear end portion of the flow inducing cutting hole.
FIG. 11 is an explanatory diagram illustrating a state in which a cutting edge of a perforated plate according to the present invention is located in a dense induction cut region, which is the rear end of the flow inducing cutting hole, and cuts the foreign matter while pressing the slide.
12 is a view illustrating a state in which a cutting edge of a perforated plate according to the present invention is cut along an inclined surface of a trimming cutting slope line while passing through a dense induction cutting area which is the rear end of the flow inducing cutting hole and cutting foreign matters at an intersection with the cutting edge Fig.
FIG. 13 is an explanatory diagram illustrating a state in which a cutting edge of a perforated plate according to the present invention completely cuts a foreign object at an intersection with a cutting corner line in a cutting region after a dense induction cutout region, which is the rear end of the flow inducing cutter.
FIG. 14 is a perspective view illustrating a state in which a cutting edge portion of a perforated plate according to an exemplary embodiment of the present invention is cut to a large thickness.
15 is a view showing an embodiment in which a perforated plate according to the present invention is installed on an underwater pump.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

That is, the perforated plate 30 for the submersible pump 10 according to the present invention and the submerged pump 10 having the perforated plate 30 have a structure in which the submerged pump 10 is placed in water as shown in FIGS. 1 to 15, To an apparatus for pumping water by a pump motor (13) which is separately supplied with power and is rotating. Particularly, the perforated plate 30 is provided so as to prevent the impeller 15 of the submersible pump 10 from being damaged by cutting foreign substances contained in the water, thereby achieving smooth pumping.

Generally, living sewage is collected separately from stormwater, sewage treated and discharged to the outside. Thus, it prevents natural ecology from being destroyed by living sewage.

Living sewage contains a large amount of foreign matter, and these foreign objects have various forms. Vinyl or cloth, plastic, or even metal pieces are also included in sewage. Of course, relatively hard iron or steel may be caught by a magnet or the like, but when such a foreign matter is not filtered out, the impeller 15 having a large number of wings may be damaged due to the foreign matter being introduced into the underwater pump.

In order to prevent this, the cutting blade 20 is provided on the inlet 11 side of the submersible pump 10 according to the present invention. In addition, rather than rotating the cutting blade 20 only, the piercing plate 30 is installed to intersect the cutting blade 20 so as to more effectively cut foreign matter.

The configuration of the present invention will be described in more detail.

And an underwater pump 10 for pumping sewage containing foreign matter from the inlet 11 to the outlet 12 by the impeller 15 which receives the rotational force of the pump motor 13 through the rotary shaft 14 will be.

The underwater pump 10 is provided with a perforated plate 30 connected to the inlet 11 side and formed with a plurality of holes so as to pass foreign matter and sewage, And a cutting blade 20 for cutting the foreign matter.

The piercing plate 30 is formed with a shaft hole 31 through which the rotating shaft 14 passes and transmits the rotating force of the pump motor 13 to the cutting blade 20.

A bolt hole (32) for fixing the pump to the underwater pump body is formed, and the piercing plate (30) is fixed to the underwater pump body by the fastening bolt (16).

And a flow-induced cutting hole 33 through which the sewage flows together with the foreign matter.

As shown in FIG. 4, the flow-induced cutting hole 33 is a portion through which the cutting blade 20 passes first, as viewed in the direction in which the cutting blade 20 rotates, and a large area induction flow region 35 Is formed. As described above, the cutting blade 20 is formed as a large-sized space through which the foreign matter and sewage flow smoothly. By forming the large-area induction flow region 35 having such a large area, foreign matter, sewage, and the like continue to flow to the impeller 15, which continuously rotates, thereby generating a load in the rotation operation of the impeller 15 So that the operation of the underwater pump 10 is smooth as a whole.

Next, the cutting blade 20 passes through the large-area induction flow region 35 and then passes through the narrow pressure cutting region 36, which is a gradually narrowed region. As a result, when the cutting blade 20 passes through the narrow pressure cutting area 36 while pushing the foreign substances in the large area induced flow area 35 that has passed the cutting blade 20, the cutting blade 20 gradually narrows and collects the foreign materials to one side. That is, in order to cut a foreign object, it may be cut more easily if it is cut to some extent rather than individually laid separately. Therefore, it is possible to more surely cut the foreign matter. On the other hand, since the sewage is sucked into the impeller 15 side irrespective of the cutting blade 20 although the sewage may be slightly influenced, the entire area of the large area induction flow region 35 is moved along the cutting blade 20, The large area induced flow area 35 of the cutting blade 20 becomes a state in which foreign matter is removed to a certain extent because it is collected in the narrow pressure cut area 36. [ Therefore, the cutting blade 20 has an advantage that the sewage can flow more smoothly into the large area induction flow region 35 where the foreign matter is removed to some extent.

In the piercing plate 30 for a submerged pump 10 according to the present invention, the flow-induced cutting hole 33 is formed in a region of a radius of the rotation of the cutting blade 20, 43).

That is, not only the small size holes but also a large area are formed, so that a larger amount of foreign substances are pressed to the object and then cut, thereby improving the cutting efficiency. In addition, foreign matter and sewage are passed through a wide area and are cut by pressing, so that foreign matter and sewage can flow smoothly.

And is located outside the compression inducing zone 43 so that the cutting blade 20 is out of the range of the radius in which the cutting blade 20 rotates, (41).

In other words, in the conventional technologies, since foreign matter or holes through which sewage flows are formed small, foreign substances may block the holes, which would interfere with the flow of sewage as a whole.

On the other hand, in the submersible punch for a submersible pump according to the present invention, the foreign material free flowing region 41 is formed outside the flow region of the cutting blade 20, so that relatively small foreign matter can always flow freely, The pumping will be smooth.

The flow-induced cutting holes 33 are formed in such a manner that the foreign matter introduced into the compression inducing area 43 abuts on the inwardly inclined trimming cutting inclination line 56, And the dense induction cut region 45, which is a region to be squeezed and cut, is formed.

In this dense induction cut region 45, the foreign materials in the entire pressure induction area 43 of the flow induced cutting hole 33 are pushed by the cutting blade 20 by the cutting blade 20, And the movement of the foreign matter is prevented by the slanting slant line 56 inclined inward as in the example of the accompanying drawings. Thus, the foreign matter is gathered by the trimming cutting oblique line 56, so that the cutting blade 20 is gradually intersected with the trimming cutting oblique line 56. As a result of the intersection between the cutting blade 20 and the trimming cutting oblique line 56, the foreign substances between them are cut off.

Accordingly, the cutting blade 20 and the trimming-cutting oblique line 56 intersect with each other at a predetermined angle different from each other in an oblique direction, so that they are intersected with each other like scissors to cut foreign substances more effectively. Therefore, even if the amount of foreign matter is high or hard, it cuts while intersecting like scissors, so that the foreign matter is effectively cut.

In addition, the flow-induced cutting hole 33 is provided with a cut-off corner line 57, which is the end of the flow-induced cutting hole 33, with respect to the rotation direction of the cutting blade 20, (47) which cuts the foreign matter between the cutting edge line (20) and the cutting corner line (57) and is the area at the tip of the cutting corner line (57).

A cutting corner line 57 is formed at the last end of the flow inducing cutting hole 33 so that the cutting corner line 57 and the cutting blade 20 are in contact with each other They are completely crossed with each other and completely cut off the remaining foreign materials.

As a result, the foreign matter that has been slowly cut while being pushed from the compression inducing area 43 is finally cut in the cutting area 47 while intersecting the cutting corner line 57 and the cutting blade 20.

The straight or curved lines constituting the edge portions of the hole in which the flow-induced cutting hole 33 is formed will be described.

This flow-induced cutting hole 33 generally forms a large space when the cutting blade 20 is first touched, while the later portion of the cutting blade 20 is gradually narrowed to effectively cut the foreign matter Thereby forming an inclined line. As a result, the cutting blade 20 is continuously rotated to cut the foreign matter in one direction, and is cut at the intersection like scissors, thereby smoothly flowing the sewage flow at all times.

Hereinafter, the lines of the boundary portion in the form of the flow inducing cutting hole 33 will be described.

In other words, since the cutting blade 20 is rotated, an arc-shaped leading inflow curve line 51 having a large radius is provided at the front end side boundary portion which first comes into contact with the flow inducing cutting hole 33. In the illustrated example, the leading inflow curve line 51 is formed in an arc shape as an example. In addition, the inflow curve line 51 may be formed of a straight line, a triangle, or a polygonal shape.

An induction inner line 52 connecting to the inward direction end of the leading inflow curve line 51 and forming a boundary between the flow induction cutting hole 33 and the shaft hole 31 is formed, There is provided a flow outer line 53 which is connected to the outward direction end of the inlet curve line 51 and makes an outer directional boundary at the flow induced cutting hole 33. [

The induction inner line 52 and the outer flow line 53 may be formed concentrically with the axial hole 31 at the center of the perforated plate 30 in the entire flow inducing cutting hole 33. In the region adjacent to the induction inner line 52, the foreign matter is gathered in one place and then the cutting regions are in contact with each other. In the opposite flow outer line 53, the cutting blade 20 is not in contact with the foreign matter and sewage A flowable area will be encountered.

And a flow switching line 54 which is connected to the flow outer line 53 and which is connected to the other side of the inclined flow pressure regulating line 55 at the end of the free flow area 41 and forms an arc.

Also provided is a tapered flow pressure ramp line 55 which interfaces with the flow diversion line 54 and forms the boundary between the end of the free flow region 41 and the flow diversion line. Thus, the flow outer line 53, the flow conversion line 54, the flow pressure gradient line 55, and the like form the boundary of the area where the cutting blade 20 does not touch. Of course, foreign matter which has flowed to some extent may be cut by cutting blades 20 rotating at a high speed, and some weak foreign substances may be cut off as it touches the downstream flow pressure slant line 55.

Next, the boundary line related to the pressing inducing area 43, the dense induction cutting area 45, the cutting area 47 and the like, which are the areas where the foreign substances are concentrated after being passed through the cutting blade 20, will be described. As described above, the induction inner line 52 constituting the boundary line on the inner side of the circle center of the flow inducing cutting hole 33 is provided.

The foreign matter of the compression induction area 43 is densified by the cutting blade 20 into the dense induction cut region 45 and the foreign matter of the pressing induction region 45 is pressed against the cutting blade 20, A sloping trimming cutting oblique line 56 for cutting the crossing foreign matter while pressing it in an oblique direction is provided. This trimming-cutting oblique line 56 is a portion where the foreign matter comes in contact with the cutting inducing region 43 from the cutting blade 20. So that foreign matter can no longer proceed or be cut off by the trimming cutting oblique line 56 or pushed in the oblique direction of the trimming cutting oblique line 56 to move the foreign matter into the cutting area 47.

Particularly, these trimming-cutting oblique lines 56 intersect with the cutting blade 20 to cut foreign matter between them by crossing each other.

Next, a cutting corner line 57 is formed which forms a boundary of the end portion in the rotating direction of the rotating cutting blade 20 and forms an arc, and cuts the foreign matter at the intersection with the cutting blade 20 in the cutting area 47.

This cutting corner line 57 is the boundary line of the last part finally passing through the flow-induced cutting hole 33 while the cutting blade 20 continues to rotate. Therefore, the foreign objects pushed from the contact inducing area 43 and the dense induction cut area 45 passing through the cutting blade 20 are gathered in the cutting area 47 which is the tip of the final cutting corner line 57. Thus, the cutting blade 20 crosses the cutting corner line 57 and finally cuts off the foreign substances gathered in the remaining cutting area 47. Thus, the cutting blade 20 cuts all foreign substances that can be cut.

Of course, since the cutting blade 20 again passes through the flow inducing cutting hole 33, the foreign substances are gathered and pressed again, a part of the cutting is performed at the intersection, and the process of cutting by the final cutting corner line 57 is continuously repeated.

And a cutting inner slanting line 58 which slants in a direction opposite to the slanting slanting line 56 and cuts the foreign matter in the cutting area 47 while pressing it in the slanting direction. The foreign substances positioned on the center side of the pier plate 30 are gathered by the cutting inner slanting line 58 which is an inward portion of the flow guiding cutter 33 and then pressed and pushed in the slanting direction of the cutting inner slanting line 58, ) And the cutting inner slanting line (58). The foreign matter not yet cut is finally cut at the intersection of the cutting corner line 57 and the cutting blade 20 after reaching the cutting area 47.

As described above, according to the present invention, since the sewage flows freely to the impeller side irrespective of the cutting blade 20 in some regions, i.e., the foreign material free flow region 41, the flow of sewage in the underwater pump 10 is continuously performed, On the other hand, since the cutting edge 20 of the cutting blade 20 pushes the foreign matter backward, the pressure inducing zone 43 where the cutting blade 20 passes first forms a vacant space in which the cutting blade 20 is removed, And more smoothly.

Thus, the flow of sewage is always performed by the foreign material free flow region 41 and the compression inducing region 43, and the pumping action by the submersible pump 10 is stably performed.

On the other hand, the foreign substances in the compression inducing area 43 are always pushed by the cutting blade 20, so that the foreign matter is removed in the compression inducing area 43 and only the sewage can flow, The foreign substances in the cut area 20 are pressed and pressed by the dense induction cut area 45 and the cut area 47 by the cutting blade 20. In the dense induction cut region 45, the cut is cut like a scissors while being pressed in the direction of the inclination of the intersection of the cutting blade 56 and the cutting inner blade 58 and the cutting blade 20.

In the final cutting area 47, the remaining foreign substances are cut at the intersections of the cutting corner line 57 and the cutting blade 20 and the like.

Since the foreign substances are gathered and pressed and then cut, the cutting effect due to the intersection of the respective lines and the cutting blade 20 is cut as the scissors are cut, thereby further increasing the cutting effect, thereby remarkably improving the cutting efficiency.

FIG. 5 is a graph showing the relationship between the number of the divided areas of the perforated plate 30 and the number of the divided areas of the perforated plate 30, The range (g) and the foreign material are divided into the pressure cutting range (h) for pressure cutting.

The angle d between the direction in which the flow pressure slanting line 55 and the trimming cutting slanting line 56 are directed with respect to the direction of the flow of the foreign material free flowing region 41 can be an angle of 100 ° to 120 ° There will be. In general, when the angle is less than 100 degrees, the inclination angle of the trimming cut-off line 56 with respect to the cutting blade 20 is reduced, so that the pressing action at the inclined surface portion can be weakened.
If the angle is inclined by more than 120 degrees, the inclined surface may become too long, thereby reducing the space for collecting the foreign substances and cutting the foreign matter. The angle d between the direction in which the flow pressure slanting line 55 and the trimming cutting slanting line 56 are directed with respect to the direction in which the foreign material free flow region 41 is oriented may be substantially 110 °.

The width of the compression inducing area 43 is 3.2 to 8.9 times wider than the width of the dense induction cut area 45 and the cut area 47. [

If the magnification ratio is less than 3.2 times, the density can be decreased. If the magnification is more than 8.9 times, too much foreign matter may be gathered and the cutting may not be performed well.

The width of the compression inducing area 43 may be about 4.5 times as large as the width of the dense induction cut area 45 and the cut area 47. [

The sum of the areas of the compression inducing area 43, the dense induction cut area 45 and the cutting area 47 through which the cutting blade 20 passes is determined with respect to the foreign material free flow area 41 in which foreign matter and sewage freely flow, The width ratio may be about 1: 1.2 to 1: 1.6, and more preferably about 1: 1.4. The width ratio of the remaining region as compared with the foreign material free flow region 41 is determined by the shape of the entire flow induced cutting hole 33, the inclined slope of the flow pressure sloping line 55, the slope cutting slope line 56, It may be determined.

The structure of the perforated plate 30 coupled to the submersible pump 10 according to the present invention will be described collectively by means of the impeller 15 that receives the rotational force of the pump motor 13 through the rotary shaft 14, And a plurality of holes are formed on the side of the inflow section 11 so as to flow foreign matter and sewage to the side of the outflow section 12. The cutting blade 20 and the cut- And includes a shaft hole 31 through which the rotary shaft 14 passes, a bolt hole 32 for fixing to the underwater pump body, and a flow induction cutting hole 33 through which sewage flows together with foreign matter .

The flow-induced cutting hole 33 is provided with a compression inducing region 43 which is a region corresponding to a radius of the radius of rotation of the cutting blade 20, A foreign matter free flow region 41 which is an area outside the range of the radius in which the blade 20 is rotated and which is a region through which foreign matter and sewage pass without contact with the cutting blade 20; A dense induction cut region 45, which is a region where the foreign substance is pressed and cut by being pushed in an oblique direction of the trimming cut oblique line 56 while contacting the inwardly inclined trimming cut oblique line 56, The foreign matter is cut between the cutting blade 20 and the cutting corner line 57 while preventing the rotation of the foreign matter by the cutting corner line 57 which is the end of the flow induced cutting hole 33 The cutting area, which is the area at the tip of the cutting corner line (57) (47).

2, 14, and so on, the perforated plate 30 according to the present invention, which is provided as described above, is provided with a blade cutting portion 61 for cutting foreign materials in contact with the cutting blade 20, The foreign matter is cut by the intersection with the cutting blade 20 at the cutting contact portion 62 which is the edge portion of the flow inducing cutting hole 33 by the blade cutting portion 61.

2, etc., the overall thickness of the perforated plate 30 may be set to a predetermined thickness so as to form a flat surface. In general, the perforated plate 30 may have a total thickness of about 5 to 10 mm, It is preferable that the thickness a is made to be 8 mm so as to maintain a solid state.

Further, as in the example of FIG. 14, the cutting blade 20 is contacted to strengthen the blade cutting portion 61 and the cutting contact portion 62 so as not to be damaged by foreign matter such as vegetable foreign matter, plastic material as well as metallic foreign matter It might be. That is, the thickness of the cut portion 61 may be thicker than the thickness of the perforated plate a by the thickness b of the cut portion 61 of the cut portion 61. In general, the thickness (b) of the blade cut portion may be formed to be approximately 1 to 5 mm thicker than the punched sheet thickness (a). More preferably, the thickness b of the blade cut portion may be formed to be thicker than the punched sheet thickness a by about 2 mm. Thus, even if the cutting process with various kinds of foreign materials is performed for a long time, the perforated plate can be easily prevented from being damaged.

In addition, the heat treatment may be performed so that the blade-cut portion 61, which is so thick, is made more rigid. Particularly, the cutting contact portion 62, which is in direct contact with the cutting blade 20, is separately heat treated so as to have a high strength, so that it is prevented from being easily damaged even in the cutting process of a hard foreign material. Such a high-strength heat treatment can be generally applied to known heat treatment techniques, and a technical explanation thereof will be omitted.

As described above, the cutting contact portion 62 or the like, which actually cuts the foreign matter with the thickness of the blade cut portion 61 contacting the cutting blade 20, is made thicker than other portions of the perforated plate 30, So that it can be used for a long time even if it is subjected to a cutting process for a hard foreign material for a long time.

By effectively cutting off the foreign substances contained in the sewage water by the pier plate 30 thus prepared, the pumping action of the whole submerged pump 10 to the sewage water is smoothly performed, and the damage of the members such as the impeller 15 is prevented, Is less than that of the prior art.

In addition, some foreign substances are not merely cut, but are pushed to one side to compress the sewage to a space in which foreign matter is removed, thereby pumping the entire submersible pump 10 stably. As a result, the discharge flow rate due to the pumping in the submersible pump 10 is increased as compared with the conventional one and the desired predetermined flow rate is maintained.

On the other hand, instead of simply cutting the foreign object, the cutting blade 20 cuts the foreign object at the intersection as in the scissors by crossing with the slope in the process of passing the cutting blade 20, thereby improving the cutting efficiency and increasing the efficiency of foreign matter removal.

As a result, the pumping action by the impeller 15 can be stably performed without clogging due to a foreign material such as a crushed material.

Conventional Perforated Plate
Discharge flow rate Application of the invention perforated plate
Discharge flow rate Increased discharge flow The first pump 26 m ³ / hr 31 m ³ / hr 5 m ³ / hr The second pump 23 m ³ / hr 28 m ³ / hr 5 m ³ / hr Example form

(Comparison of Discharge Flow Rate of Sewage by Conventional Perforated Plate and Perforated Plate in the Present Invention)

Conventionally, the perforations of the perforated plate are merely circular, so that only a simple cutting operation is performed by the rotating cutting edge. In the present invention, however, the cutting blade 20 induces the pressing and densification of the foreign matter, The total discharge flow rate is increased.

As a result, damage to the members such as the impeller 15 is prevented and operation of the submersible pump 10 is stable, so that the maintenance cost can be reduced, and the discharge flow rate of the sewage as a whole is increased to improve the pumping action for the sewage. In addition, since the cutting of the foreign matter is stably performed, even if the sewage is introduced in any state, the pump for the sewage is well performed, and the stable treatment for the whole sewage treatment is performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The technical idea of the present invention should not be construed as being limited.

10: Submersible pump 13: Pump motor
15: impeller 20: cutting blade
30: perforated plate 33: flow induction cutting hole
41: foreign matter free flow region 43:

Claims (5)

The sewage containing foreign matter is pumped from the inflow section 11 to the outflow section 12 by the impeller 15 which receives the rotational force of the pump motor 13 through the rotary shaft 14,
A perforated plate 30 connected to the inflow portion 11 side and forming a plurality of openings to allow foreign matter and sewage to pass; And
And a cutting blade (20) coupled to a front end of the perforated plate (30) and cutting a foreign substance while rotating,
The perforated plate (30)
A shaft hole (31) through which the rotation shaft (14) passes;
A bolt hole (32) for fixing to the underwater pump body; And
And a flow-induced cutting hole (33) through which the sewage flows together with the foreign matter,
The flow-induced cutting hole (33)
A compression inducing area 43 which is a region corresponding to a radius of the radius of rotation of the cutting blade 20;
A foreign matter free flow region 41 (a region through which the foreign matter and the sewage pass) without being in contact with the cutting blade 20 is located outside the range of the radius where the cutting blade 20 is rotated outwardly of the compression inducing region 43, );
A foreign matter introduced into the compression induction area 43 is pressed against the slanting slope line 56 in contact with the slanting slant line 56 inclined inwardly and pressed and cut, 45); And
The cutting edge 20 of the cutting blade 20 is rotated by the cut corner line 57 which is the end of the flow inducing cutter 33 to prevent the foreign matter from rotating, And a cutting area 47, which is the area of the tip of the cutting corner line 57,
The flow-induced cutting hole (33)
A leading inflow curve line 51 having an arc shape and having a large radius is formed at the tip end side boundary portion of the flow inducing cutter 33 that is initially in contact with the cutting blade 20 when the cutting blade 20 is rotated;
An induction inner line (52) extending from the inward direction end of the leading inflow curve line (51) and forming a boundary between the flow induction cutting hole (33) and the shaft hole (31) direction;
A flow outer line 53 extending from the outward direction end of the leading inflow curve line 51 and forming an outward boundary with the flow inducing cutter 33;
A flow conversion line 54 connected to the flow outer line 53 and forming an arcuate continuity with the other of the inclined flow pressure gradient line 55 at the end of the free flow region 41;
A sloping flow pressure ramp line 55 bounding the flow diversion line 54 and bounding the end of the foreign material free flow region 41;
A foreign matter in the compression induction area 43 is densely packed in the dense induction cut area 45 by the cutting blade 20 and the inclined trimming cut oblique line 45 is cut at the intersection with the cutting blade 20 while pressing the foreign matter in the oblique direction. (56);
A cutting corner line 57 forming a boundary of an end portion of the rotating cutting blade 20 in the rotational direction and cutting an object at an intersection with the cutting blade 20 in the cutting area 47; And
And a cutting inner slanting line (58) sloping in a direction opposite to the slanting slanting line (56) and cutting the foreign matter in the cutting area (47) while pressing it in a slanting direction.
delete delete The method according to claim 1,
An angle d between the direction of the flow pressure slant line 55 and the direction of the slant cutting slant line 56 with respect to the direction of the flow of the foreign material free flow region 41 forms an angle of 100 ° to 120 °,
Wherein the width of the compression inducing area (43) is as wide as 3.2 to 8.9 times the width of the dense induction cut area (45) and the cut area (47).
The pump motor 13 pumps the sewage containing a large number of foreign substances from the inlet 11 to the outlet 12 by the impeller 15 having received the rotational force from the rotary shaft 14,
Wherein a plurality of holes are formed on the side of the inflow part (11) to cut off foreign matter at an intersection with a cutting blade (20) provided with foreign matter and sewage,
A shaft hole (31) through which the rotation shaft (14) passes;
A bolt hole (32) for fixing to the underwater pump body; And
And a flow-induced cutting hole (33) through which the sewage flows together with the foreign matter,
The flow-induced cutting hole (33)
A compression inducing area 43 which is a region corresponding to a radius of the radius of rotation of the cutting blade 20; And
A foreign matter free flow region 41 (a region through which the foreign matter and the sewage pass) without being in contact with the cutting blade 20 is located outside the range of the radius where the cutting blade 20 is rotated outwardly of the compression inducing region 43, );
A foreign matter introduced into the compression induction area 43 is pressed against the slanting slope line 56 in contact with the slanting slant line 56 inclined inwardly and pressed and cut, 45); And
The cutting edge 20 of the cutting blade 20 is rotated by the cut corner line 57 which is the end of the flow inducing cutter 33 to prevent the foreign matter from rotating, And a cutting area 47, which is the area of the tip of the cutting corner line 57,
The flow-induced cutting hole (33)
A leading inflow curve line 51 having an arc shape and having a large radius is formed at the tip end side boundary portion of the flow inducing cutter 33 that is initially in contact with the cutting blade 20 when the cutting blade 20 is rotated;
An induction inner line (52) extending from the inward direction end of the leading inflow curve line (51) and forming a boundary between the flow induction cutting hole (33) and the shaft hole (31) direction;
A flow outer line 53 extending from the outward direction end of the leading inflow curve line 51 and forming an outward boundary with the flow inducing cutter 33;
A flow conversion line 54 connected to the flow outer line 53 and forming an arcuate continuity with the other of the inclined flow pressure gradient line 55 at the end of the free flow region 41;
A sloping flow pressure ramp line 55 bounding the flow diversion line 54 and bounding the end of the foreign material free flow region 41;
A foreign matter in the compression induction area 43 is densely packed in the dense induction cut area 45 by the cutting blade 20 and the inclined trimming cut oblique line 45 is cut at the intersection with the cutting blade 20 while pressing the foreign matter in the oblique direction. (56);
A cutting corner line 57 forming a boundary of an end portion of the rotating cutting blade 20 in the rotational direction and cutting an object at an intersection with the cutting blade 20 in the cutting area 47; And
And a cutting inner slanting line (58) inclined in a direction opposite to the slanting slant line (56) and cutting the foreign matter in the cutting area (47) while pressing it in a slanting direction.

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