KR101831191B1 - shafts of double-cutting rotary pumps for high vacuum and wear resistance - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a rotary shaft of a double-cutting rotary pump for high vacuum and abrasion resistance, and more particularly, The abrasion preventing member is provided on the outer circumferential edge of the drive shaft and the interlocking shaft which rotate in contact with each other so as to prevent the abrasion, The present invention relates to a rotary shaft of a double-cutting rotary pump for high vacuum and abrasion resistance so that a member can be maintained in a high vacuum state while serving as a rubber packing.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to double-cutting rotary pumps for high vacuum and abrasion resistance,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving and interlocking shaft of a rotary pump having an efficient cutting structure and wear resistance in order to smooth foreign matter of a fluid while being used in a rotary pump to facilitate pumping transfer.

Conventionally, a centrifugal pump is generally used as a pump for pumping a fluid containing a large amount of various foreign substances such as industrial waste sludge, industrial wastewater and the like.

However, since highly viscous fluids such as sludge and sludge mainly contain a large amount of fibrous materials and various foreign substances (such as wire or gloves), not only the pumping efficiency is lowered but also foreign substances are trapped between the rotor and the housing, There is a problem that the operation is not performed smoothly due to frequent occurrence of a failure.

Accordingly, development of a device for facilitating the feeding of the pump by easily cutting the foreign substance contained in the fluid is being developed.

Korean Registered Patent No. 10-0307044 (registered on August 17, 2001)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a driving shaft and an interlocking shaft which are rotatably supported in a rotary pump, A wear preventive member of a cemented carbide is formed so as to reduce abrasion and increase cutting efficiency at an end portion cutting a foreign substance in the fluid and a large number of abrasion reducing portions are formed also on the outer circumferences between the drive shaft and the interlocking shafts, And a high vacuum and abrasion resistance structure having a structure in which the inside of the housing is maintained in a highly vacuum state more efficiently and the pumping transfer efficiency is increased owing to the role of the rubber packing of the abrasion reducing section made of the elastic member, It is to provide the rotary shaft of the double-cutting rotary pump.

Other objects and advantages of the present invention will be described hereinafter and will be understood by the embodiments of the present invention. Further, the objects and advantages of the present invention can be realized by the means and the combination shown in the claims.

SUMMARY OF THE INVENTION The present invention, as a means for solving the above problems,

(10) for holding a high vacuum, which is provided in the housing (10) of a rotary pump for cutting a fluid to be conveyed, such as a shaft fraction containing foreign matter, industrial sludge and wastewater, A drive shaft 20 installed to be rotatable; An interlocking shaft (30) connected to the drive shaft (20) by power transmission means so as to be rotatable, the interlocking shaft (30) being rotated against the outer circumference of the drive shaft (20); The plurality of drive shafts 20 and the interlocking shafts 30 are provided so as to be positioned on the same vertical line on the outer circumference of the drive shaft 20 and the interlocking shafts 30, A cutting portion 40 for making the surface smooth; The abrasion-reducing section 30 is provided internally at the outer periphery of the drive shaft 20 and the outer peripheral edge of the interlocking shaft 30, and protrudes outward to a predetermined portion to reduce abrasion of the sugar plate between the drive shaft 20 and the interlocking shaft 30. [ (50); The driving shaft 20 and the interlocking shaft 30 are formed on the outer circumferences of the driving shaft 20 and the interlocking shaft 30 and are formed between the cutting portion 40 and the cutting portion 40 so as to be positioned on the same vertical line. A depression (60) for allowing the cutting portion (40) of the interlocking shaft (30) to interlock with the inner periphery at a predetermined spacing (H); And the cutting portion 40 has a lower edge E1 and a lower edge E2 on the inlet 11 side of the portion where the horizontally flowing fluid is branched in the upward and downward directions inside the housing 10, The cutting portion 40 is rotated and transferred to all four portions on the discharge port 12 side and the lower edge portions E3 and E4 of the portion where the branching fluid is reintegrated and the foreign material contained in the fluid to be transported And is cut.

As described above, the present invention has an effect of reducing the wear of the cutting portion while efficiently cutting foreign matter contained in the fluid.

Further, the present invention has the effect of reducing the occurrence of abrasion between the drive shaft and the interlocking shafts, which are rotated in contact with each other.

Further, according to the present invention, since the abrasion-reducing portion provided on the drive shaft and the interlocking shaft functions as a rubber packing for the purpose of generating abrasion, the internal vacuum can be maintained at a high vacuum.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 and Figure 2 are views of one embodiment showing a drive and interlocking shafts of a rotary pump according to the present invention.

Before describing in detail several embodiments of the invention, it will be appreciated that the application is not limited to the details of construction and arrangement of components set forth in the following detailed description or illustrated in the drawings. The invention may be embodied and carried out in other embodiments and carried out in various ways. It should also be noted that the device or element orientation (e.g., "front,""back,""up,""down,""top,""bottom, Expressions and predicates used herein for terms such as "left,"" right, "" lateral, " and the like are used merely to simplify the description of the present invention, Or that the element has to have a particular orientation. Also, terms such as " first "and" second "are used in this specification and the appended claims for the purpose of description and are not intended to indicate or imply their relative importance or purpose.

The present invention has the following features in order to achieve the above object.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

According to one embodiment of the present invention,

(10) for holding a high vacuum, which is provided in the housing (10) of a rotary pump for cutting a fluid to be conveyed, such as a shaft fraction containing foreign matter, industrial sludge and wastewater, A drive shaft 20 installed to be rotatable; An interlocking shaft (30) connected to the drive shaft (20) by power transmission means so as to be rotatable, the interlocking shaft (30) being rotated against the outer circumference of the drive shaft (20); The plurality of drive shafts 20 and the interlocking shafts 30 are provided so as to be positioned on the same vertical line on the outer circumference of the drive shaft 20 and the interlocking shafts 30, A cutting portion 40 for making the surface smooth; The abrasion-reducing section 30 is provided internally at the outer periphery of the drive shaft 20 and the outer peripheral edge of the interlocking shaft 30, and protrudes outward to a predetermined portion to reduce abrasion of the sugar plate between the drive shaft 20 and the interlocking shaft 30. [ (50); The driving shaft 20 and the interlocking shaft 30 are formed on the outer circumferences of the driving shaft 20 and the interlocking shaft 30 and are formed between the cutting portion 40 and the cutting portion 40 so as to be positioned on the same vertical line. A depression (60) for allowing the cutting portion (40) of the interlocking shaft (30) to interlock with the inner periphery at a predetermined spacing (H); And the cutting portion 40 is formed with the lower edges E1 and E2 on the inlet 11 side of the portion where the horizontally flowing fluid is branched in the upward and downward directions inside the housing 10, The cutting portion 40 is rotated and transferred to all four portions on the discharge port 12 side and the lower edge portions E3 and E4 of the portion where the branching fluid is reintegrated and the foreign material contained in the fluid to be transported And is cut.

The cutting part 40 has a mounting part 41 inserted into the driving shaft 20 or the interlocking shaft 30 and a mounting part 41 having a relatively larger diameter than the mounting part 41, (42) extending in a straight line shape corresponding to the broken straight section (61) of the recess (60), spaced apart from the straight section (61) of the inner periphery of the depression (60) by a predetermined distance; A narrowing portion 43 whose diameter is gradually narrowed in an oblique shape as the diameter of the mounting portion 41 in the extending portion 42; And a control unit.

The cutting portion 40 may have a groove 44 formed at an end of the cutting insert 40 which is inserted into the recess 60 and the wear prevention member 45 may be inserted into the groove 44, The cutting ability of the foreign matter is improved and the occurrence of abrasion with the peripheral edge of the housing 10 in contact therewith is reduced.

The abrasion reducing part 50 is formed on the driving shaft 20 and includes a plurality of abrasion reducing parts 50 spaced apart from each other and a plurality of abrasion reducing parts 50 formed on the interlocking shaft 30 And the abrasion reducing section 50 is directly brought into contact with the outer circumferential edge of the abutting shaft.

The depressed portion 60 includes a straight portion 61 that is drawn toward the drive shaft 20 or the interlocking shaft 30; A rounding portion 62 which is subsequently formed as an arc in the straight line portion 61; .

The round portion 62 has a cutting portion 40 whose one end is inserted into the drive shaft 20 or the interlocking shaft 30 and the other end is projected into the depression 60 to be accommodated in the depression 60, (70); Is further provided.

The cutting portion 40 is formed on the inlet 11 side and the lower edge portions E1 and E2 of the housing 10 or in the housing 10 in the direction of rotation of the driving shaft 20 and the interlocking shaft 30. [ The cutting portion 40 is rotated and transferred on the discharge port 12 side and the lower edge portions E3 and E4 of the discharge ports 10 and 10 and the foreign substance contained in the fluid to be transported is cut.

Hereinafter, the rotary shaft of the double-cutting rotary pump for high vacuum and wear resistance according to a preferred embodiment of the present invention will be described in detail with reference to FIG. 1 to FIG.

The rotary shaft of the double-cutting rotary pump for high vacuum and abrasion resistance according to the present invention is installed in the housing 10 of the rotary pump and cuts the fluid to be conveyed such as shaft powder containing foreign matter, industrial sludge and wastewater, And includes the drive shaft 20, the interlocking shaft 30, the cutting portion 40, the abrasion reducing portion 50, and the depressed portion 60.

The driving shaft 20 is rotatably driven by a separate driving means inside the housing 10 having a high vacuum state. The driving shaft 20 is rotatably driven by driving means (such as a motor) and power transmission means (belt, chain, etc.) So as to be able to transmit power.

The driving shaft 20 and the interlocking shaft 30 are separated from the outside of the housing 10 by the driving shaft 20 and the outer peripheral edge of the driving shaft 20, And the driven shaft 30 is also driven by the rotation of the drive shaft 20. [0034] The rotary drive structure of the drive shaft 20 and the interlocking shaft 30 of the rotary pump is well known in the art, and a detailed description thereof will be omitted.

The interlocking shaft 30 is provided with a cutting portion 40 to be described later at the outer periphery of the drive shaft 20 and the interlocking shaft 30 while the outer periphery of the interlocking shaft 30 is in close contact with the drive shaft 20, So that the foreign substance contained in the fluid can be cut through the part 40.

The driving shaft 20 and the interlocking shaft 30 are formed with a cutting portion 40, a wear reducing portion 50, and a depressed portion 60, which will be described in detail below.

The cutting portion 40 protrudes from the outer periphery of the driving shaft 20 and the interlocking shaft 30 to cut foreign matter contained in the fluid as described above.

The cutting portion 40 for this purpose includes a mounting portion 41, an extension portion 42, and a narrowed portion 43

The mounting portion 41 is inserted and fixed at a predetermined depth toward one end of the driving shaft 20 or the interlocking shaft 30 and the extending portion 42 is fixed to the driving shaft 20 or the interlocking shaft 30 at the mounting portion 41. [ (Thickness) of the driving shaft 20 and the concave portion 60, which is recessed and engaged with the driving shaft 20 and the interlocking shaft 30 to be described later, And is formed so as to extend in a straight line shape having a shape corresponding to the outermost straight section 61 and to be spaced apart from the inner circumference (more precisely, the straight section 61) And is inserted into the depression 60.

The narrowed portion 43 is further extended outwardly from the above-described extended portion 42, and the diameter is gradually narrowed in an oblique shape so as to become the same as the straightened portion of the mounting portion 41.

The cutting portion 40 according to the present invention is characterized in that a groove 44 is formed at an end of the narrowed portion 43 which is inserted into the depression 60 and a groove 44 is formed in the narrowed portion 43 to prevent abrasion of the cemented carbide The member 45 can be inserted into the housing 10 so that the cutting ability of the foreign substance contained in the fluid can be improved and the occurrence of abrasion with the peripheral edge of the housing 10 in contact with the fluid can be reduced.

The cutting portion 40 is protruded from the outer periphery of the driving shaft 20 and the interlocking shaft 30 so as to be positioned on the same vertical line.

When the fluid horizontally introduced through the inlet 11 of the housing 10 is branched in the upward and downward directions from one side of the housing 10, The lower edge portions E1 and E2 on the one end side and the lower edge portions E1 and E2 of the inlet port 11 are bent in a circular and clockwise direction in the housing 10, When the moving fluid is reintegrated and a total of four portions, that is, a portion where the flow direction changes horizontally toward the discharge port 12 formed horizontally, namely, one end side and the bottom edge portions E3 and E4 of the discharge port 12, In this portion where the edge portion and the cutting portion 40 meet, foreign matter contained in the fluid to be transported is cut. That is, two portions of the driving shaft 20 and two portions of the interlocking shaft 30 correspond to each other, and foreign matter is cut at a total of four portions.

More specifically, the cutting portion 40 is cut at two positions in accordance with the rotation direction of the driving shaft 20 and the interlocking shaft 30. When the driving shaft 20 is rotated clockwise, The cutting portion 40 is rotated and fed at the lower edge portions E1 and E2 on the inlet 11 side and the foreign material portion contained in the fluid to be conveyed when the fluid 10 is passed therethrough, The cutting portion 40 is rotated and transferred on the discharge port 12 side and the lower edge portions E3 and E4 of the housing 10 in the clockwise direction and the foreign material Is cut.

The abrasion reducing section 50 is formed on the outer periphery of the driving shaft 20 and the interlocking shaft 30 and is installed in the outer periphery of the driving shaft 20 and the interlocking shaft 30, And serves to reduce abrasion of the sugar dish between the driving shaft 20 and the interlocking shaft 30.

The abrasion reducing section 50 is provided on the outer circumference of the interlocking shaft 30 of the drive shaft 20 and has a plurality of abrasion reducing sections 50 formed on the drive shaft 20, And the abrasion reducing section 50 formed on the driving shaft 20 are formed at different positions which do not correspond to each other and contacted with each other so that the abrasion reducing section 50 formed on the interlocking shaft 30 is in contact with the interlocking shaft 30, The abrasion reducing section 50 formed on the interlocking shaft 30 is brought into contact with the outer peripheral edge of the drive shaft 20 where the abrasion reducing section 50 is not formed The abrasion reducing portion 50 is directly brought into contact with the outer periphery of the abrasion preventing portion 50.

Therefore, the abrasion of the driving shaft 20 and the interlocking shaft 30, which are in contact with each other, can be reduced as compared with the conventional art. Since the abrasion reducing part 50 is made of a rubber material and functions as a rubber packing, So that the inside of the housing 10, which is kept in a vacuum state, can maintain a high vacuum state.

(Low pressure) is formed on the side of the inlet 11 through which the fluid is introduced while the driving shaft 20 and the interlocking shaft 30 come into contact with each other and rotate in a predetermined direction. In this vacuum state, And the liquid is discharged through the opposite discharge port 12. The amount of the discharged fluid depends on how well the rotor maintains the vacuum state, that is, the vacuum state inside the housing 10 formed by the rotor The more easily the liquid can be sucked through the inlet 11.

The depressed portion 60 is recessed at the outer periphery of the drive shaft 20 and the outer peripheral edge of the interlocking shaft 30. The recessed portion 60 is formed in the outer periphery of the drive shaft 20 and the interlocking shaft 30, And the cutting portion 40 of the driving shaft 20 or the interlocking shaft 30 is in contact with the cutting portion 40 so that the cutting portion 40 is in contact with the cutting portion 40.

The depression 60 is formed by the rectilinear section 61 and the rounded section 62 and is recessed.

The straight portion 61 is a portion that is drawn inward from the outer periphery of the driving shaft 20 or the interlocking shaft 30 and the round portion 62 is a portion do. When the cutting portion 40 corresponds to the depression 60, the outer periphery of the cutting portion 40 and the inner periphery of the depression 60 do not contact each other.

One end of the rounded portion 62 of the depression 60 is inserted into the drive shaft 20 or the interlocked shaft 30 while the other end of the rounded portion 62 is inserted into the recessed portion 60 And a packing member 70 protruding into the depression 60 and corresponding to and contacting the end of the cutting portion 40 accommodated in the depression 60. The packing member 70 is made of a rubber material. Thus, each of the left and right discharging sides of the fluid is brought into contact with the cutting portion 40 received in the depressed portion 60, The inside of the body 10 can be sealed with a high vacuum.

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. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

10: housing 11: inlet
12: Discharge port 20:
30: interlocking shaft 40: cutting portion
41: mounting portion 42:
43: Narrow strength portion 44: Home
45: abrasion preventing member 50: abrasion reducing portion
60: depression portion 61: straight portion
62: rounding part 70: packing member
E1, E2, E3, E4:

Claims (7)

Is provided in the housing (10) of the rotary pump for cutting a fluid to be conveyed, such as an axial flow containing foreign matter, industrial sludge and wastewater,
A driving shaft (20) rotatably installed in the housing (10) maintaining a high vacuum;
An interlocking shaft (30) connected to the drive shaft (20) by power transmission means so as to be rotatable, the interlocking shaft (30) being rotated against the outer circumference of the drive shaft (20);
The plurality of drive shafts 20 and the interlocking shafts 30 are provided so as to be positioned on the same vertical line on the outer circumference of the drive shaft 20 and the interlocking shafts 30, A cutting portion 40 for making the surface smooth;
The abrasion-reducing section 30 is provided internally at the outer periphery of the drive shaft 20 and the outer peripheral edge of the interlocking shaft 30, and protrudes outward to a predetermined portion to reduce abrasion of the sugar plate between the drive shaft 20 and the interlocking shaft 30. [ (50);
The driving shaft 20 and the interlocking shaft 30 are formed on the outer circumferences of the driving shaft 20 and the interlocking shaft 30 and are formed between the cutting portion 40 and the cutting portion 40 so as to be positioned on the same vertical line. A depression (60) for allowing the cutting portion (40) of the interlocking shaft (30) to interlock with the inner periphery at a predetermined spacing (H); And,
The cutting portion 40 is formed on the lower portion E1 and the lower portion E2 on the inlet 11 side of the portion where the fluid horizontally introduced into the housing 10 diverges in the upward and downward directions, The cutting portion 40 is rotated and transferred to all four portions on the discharge port 12 side and the lower edge portions E3 and E4 of the portion where the fluid is to be reintegrated,
The cutting portion 40 has a mounting portion 41 that is inserted into the driving shaft 20 or the interlocking shaft 30 and is inserted into the concave portion 60 while having a relatively larger diameter than the mounting portion 41, And an extension part (42) extending in a straight line shape corresponding to the wavy rectilinear part (61) of the recess (60) and spaced apart from the rectilinear part (61) And a narrowing portion 43 whose diameter is gradually narrowed in an oblique shape, which is the same as the diameter of the mounting portion 41,
The cutting portion 40 is formed with a groove 44 at an end portion thereof which is inserted into the depressed portion 60 and the abrasion preventing member 45 is inserted into the groove 44, And the occurrence of abrasion with the peripheral edge in the housing 10 to be contacted is reduced,
The abrasion reducing part 50 is formed on the driving shaft 20 and includes a plurality of abrasion reducing parts 50 spaced apart from each other and a plurality of abrasion reducing parts 50 formed on the interlocking shaft 30 So that the abrasion-reducing portion 50 is directly brought into contact with the outer periphery of the abutting shaft,
The depressed portion 60 is composed of a straight portion 61 that is drawn toward the drive shaft 20 or the interlocking shaft 30 and a rounded portion 62 that is formed by a circular arc from the straight portion 61 ,
The rounded portion 62 has one end inserted into the drive shaft 20 or the interlocking shaft 30 and the other end protruding into the depressed portion 60 so that the end of the cutting portion 40 received in the depressed portion 60 And a packing member (70)
The cutting portion 40 is formed on the inlet 11 side and the lower edge portions E1 and E2 of the housing 10 or the housing 10 along the rotation direction of the driving shaft 20 and the interlocking shaft 30. [ Wherein the cutting portion (40) is rotated and fed at the lower edge portions (E3, E4) of the discharge port (12) side and the foreign substance contained in the fluid to be transported is cut at the time of passing through. Rotation axis of cutting rotary pump.
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