KR101564310B1 - Double suction pump - Google Patents

Abstract

The present invention relates to a double suction pump. The purpose of the present invention is to provide a double suction pump capable of reducing impeller vane passing vibration and pulsation of a fluid by improving a structure of a water cutter formed in a casing of a double suction pump. According to the present invention, the double suction pump comprises: an impeller including multiple vanes in both lateral surfaces of a main plate, and for delivering speed energy to a fluid as the fluid is flowing from the both lateral surfaces; a volute part for accommodating the impeller inside, and for converting the speed energy of the fluid flowing from the impeller into pressure energy; and a casing including a discharge part for guiding the fluid passing through the volute part to an outside; Moreover, a water cutter formed in the casing is further comprised to be located in a boundary area of the volute part and the discharge part. A water cutter formation line formed by the end of the water cutter is a structure which is not in parallel with a vane formation line formed by the end of the vane. Two lines with a structure at an incline to have predetermined inclination toward the impeller are connected to have an inter-angle less than 180° based on a base line having a structure in parallel with a rotation center shaft line of the impeller, and then formed as a V-shaped structure. A vane formed in one lateral surface of a main plate of the impeller, and a vane formed in the other lateral surface of the main plate are formed in the mutually misalignment structure.

Description

Double suction pump

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dual suction pump, and more particularly, to a double suction pump capable of improving the structure of a water cutter formed in a casing to reduce pulsation of fluid and impeller vane passage vibration.

Generally, a centrifugal pump is a pump which is installed in an interior of a pump case, rotates by receiving a rotational force generated by the driving of the motor, and sucks and discharges the fluid by using the centrifugal force generated by the rotation of the impeller.

Such a centrifugal pump can be divided into a single suction pump and a dual suction pump depending on the suction structure of the fluid.

The single suction pump is a centrifugal pump having a structure for sucking and discharging fluid from only one side of the impeller. It is difficult to realize a pump system of a high performance pump due to a small suction amount of the fluid. Further, There is a problem that the bearing is easily damaged due to an excessive thrust load applied to the bearing.

The double suction pump is a centrifugal pump having a structure for sucking fluids from both sides of the impeller. Since the suction amount of the fluid is larger than that of the single suction pump, a pump system of a high lifting pump can be realized and a similar amount of fluid is sucked from both sides of the impeller , The thrust load acting on the rotating shaft, the impeller and the bearing is small.

Fig. 1 is a sectional view showing the internal structure of a conventional double suction pump, Fig. 2 is a sectional view taken along line AA in Fig. 1, Fig. 3 is a sectional view along line BB in Fig. 1, And shows a perspective view showing a structure of a vane and a water cutter.

In general, both suction pumps include an impeller 10 that receives fluid and imparts velocity energy to the fluid, a casing 20 that accommodates the impeller 10 and converts velocity energy of the fluid from the impeller into pressure energy to discharge the fluid, And a rotating shaft 30 installed on the casing 20 to support the impeller 10 and receiving power to transmit the impeller 10 to the impeller.

The casing 20 is provided with a suction unit 21 through which fluid is introduced, a volute unit 22 that converts the velocity energy of the fluid from the impeller 10 into pressure energy, A water cutter 24 is formed at the boundary between the volute portion 22 and the discharge portion 23 so as to form a discharge portion 23 for guiding the fluid that has passed through the portion 22 to the outside .

The water cutter 24 formed in the casing 20 of the conventional double suction pump is formed in a structure parallel to the vane 11 formed on the impeller 10.

In the meantime, a plurality of vanes 11 having a substantially arcuate curved structure are formed inside the impeller, and the fluid is discharged while flowing through the space between the vane and the vane when the impeller is rotated.

Therefore, the fluid discharged from the impeller is discharged as it is while maintaining the shape corresponding to the end structure of the vane.

On the other hand, when the water cutter is formed in a structure parallel to the vane, when the fluid discharged in the form corresponding to the vane end structure collides with the water cutter at the same time regardless of the position (see FIG. 4) Vane passing energy of the fluid is transferred to the water cutter as it is. This phenomenon occurs repeatedly by the number of wings per revolution of the impeller, so that the pulsation of the fluid and the impeller vane passing vibration are amplified There is a problem to be done.

Public Utility Model Publication No. 1999-002230 (published on 25.01.1999) Published Patent Publication No. 2006-0132678 (published on December 21, 2006)

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a double-suction pump which can improve the structure of a water cutter formed in a casing of a double suction pump to reduce pulsation of a fluid and impeller vane passing vibration, .

According to an aspect of the present invention, there is provided an impeller comprising: a main plate having a plurality of vanes formed on both sides of a main plate, 1. A dual suction pump comprising a casing having a volute portion for receiving the impeller therein and for converting the velocity energy of the fluid coming from the impeller to pressure energy, and a discharge portion for guiding the fluid passing through the volute portion to the outside, And a water cutter formed in the casing so as to be positioned in a boundary region between the volute portion and the discharge portion, wherein the water cutter shape line formed at the end of the water cutter is not parallel to the vane shape line formed by the end portion of the vane, The impeller having a base line having a structure parallel to the axis of rotation of the impeller, V "shape, and the vanes formed on one side surface of the main plate of the impeller and the vanes formed on the other side surface of the main plate are connected to each other so that the two lines of the inclined structure have a predetermined angle, Are formed in mutually staggered arrangement structures.

delete

delete

delete

delete

delete

According to the present invention having the above-described characteristics, the impeller vane and the water cutter are not parallel to each other but are shifted from each other, thereby reducing pulsation and impeller vane passing vibration of the fluid. Can be implemented.

1 is a sectional view showing the internal structure of a conventional double suction pump,
2 is a sectional view taken along the line AA in Fig. 1,
3 is a sectional view taken along line BB in Fig. 1,
4 is a perspective view showing a structure of a conventional impeller vane and a water cutter of a double suction pump,
5 is a structural view of a double suction pump according to the present invention,
FIG. 6 is a cross-sectional view taken along line CC of FIG. 5,
7 is an exemplary view of a walker cutter profile line and a vane profile line according to the present invention,
8 to 10 are schematic views of a water cutter according to the present invention,
11 is a perspective view of a casing and an impeller in which a water cutter having a concave recessed round structure is formed;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

5 is a structural view of a double suction pump according to the present invention, and Fig. 6 is a sectional view taken along the line C-C of Fig.

The double suction pump according to the present invention is configured such that the vane 111 formed in the impeller 110 and the water cutter 124 formed in the casing 120 are not parallel to each other but have a shifted structure and are rotated by the rotation of the impeller 110 The pulsation of the fluid and the impeller vane passing vibration, which is a vibration generated in the process of passing the fluid through the vane 111, are reduced.

The double suction pump of the present invention comprises an impeller 110, a casing 120, and a rotary shaft 130.

The impeller 110 includes a plurality of vanes 111 formed on both sides of the main plate 112.

The casing 120 includes a space S in which the impeller 110 is accommodated and the fluid is pumped, a suction portion 121 through which the fluid is introduced into the space S, A volute portion 122 for guiding the fluid discharged from the space S by rotation, a discharge portion 123 for discharging the fluid through the volute portion 122 to the outside, And a water cutter 124 positioned in a boundary region between the discharge section 122 and the discharge section 123.

The casing 120 is provided with a bearing unit 125 for supporting the rotating shaft 130 and a packing box 126 for preventing fluid leakage.

The rotating shaft 130 is rotatably supported by a bearing unit 125 installed in the casing 120. The rotating shaft 130 is coupled to the impeller 110 to rotate the power provided from a power source (110) to rotate the impeller (110).

The impeller 110, the casing 120, and the rotary shaft 130 may be configured in the same manner as a well-known dual suction pump that is widely used, and a detailed description thereof will be omitted.

However, the water cutter 124 formed in the casing 120 of the double suction pump according to the present invention is different from the vane 111 in construction.

Fig. 7 shows illustrations of a walker cutter line and a vane line according to the present invention.

The water cutter 124 according to the present invention is the same as the conventional walker cutter in that the water cutter 124 is positioned in the boundary region between the bolt portion 122 and the discharge portion 123 formed in the casing 120, Is formed so as not to be parallel to the vane shape line L2 formed by the end portion of the vane 111. In this case,

The water cutter shape line L1 is a line formed by connecting points P1 located at an end of the water cutter 124. The vane shape line L2 is a line formed by connecting the point P1 located at the end of the water cutter 124, (P2) located at the center of the vane (111).

8 to 10 show the structure of the water cutter according to the present invention.

8 shows an impeller 110 in which vanes 111 having a vertical structure are arranged on both sides of the main plate 112 so as to be staggered from each other. In the impeller 110 together with the impeller 110, The water cutter 124 formed on the impeller 110 is formed in a sloped structure so as to have a shape line having a predetermined slope toward the impeller with reference to a reference line VL having a structure parallel to the axis of rotation of the impeller 110, As shown in FIG.

9 and 10 show an impeller 110 having a structure in which vanes 111 inclined at a predetermined angle are staggered on both sides of the main plate 112. In addition to the impeller 110, The water cutter 124 formed in the casing 120 constituting the water cutter 124 may be configured to have a shape line having a structure parallel to the reference line VL parallel to the rotation center axis of the impeller 110, (See Fig. 9), or a shape having a " V " -shaped structure such that the two lines are connected to each other with an angle of less than 180 [deg.], Line (see Fig. 10).

Fig. 11 shows a perspective view of a casing and an impeller in which a water cutter having a concave recessed round structure is formed.

As described above, the shape line L1 formed at the end of the water cutter 124 is formed by a sloping straight line, a curved line, a rounded structure, a 'V' shape or the like and is parallel to the shape line L2 of the vane It is possible to prevent the fluid discharged from the impeller 110 from colliding with the water cutter at the same time by the rotation of the impeller 110 so that the pulsation of the fluid or the vane passing vibration of the impeller is prevented from being amplified This makes it possible to realize a stable double suction pump with low vibration and noise.

For example, as shown in FIG. 11, when the vane 111 of the impeller 110 is formed in a straight-line structure (refer to FIG. 11) and the water cutter 124 is formed in a recessed rounded structure, The fluid discharged from the impeller by the rotation of the vane 111 is discharged while maintaining the vertical straight shape formed by the vane 111. When the fluid having such a shape collides with the water cutter 124, 124). As a result, the vane passing energy can be dispersed to reduce the pulsation of the fluid or the vane passing vibration of the impeller.

As described above, the double suction pump according to the present invention allows the vane and the water cutter to have a structure that is not parallel to each other and to have a shifted structure so that the fluid discharged from the impeller collides with the water cutter at different positions in time to reduce pulsation and vane passing vibration There is an advantage that can be made.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

Description of the Related Art
L1: water cutter shape line L2: vane shape line
110: impeller 111: vane
112: abacus 120: casing
122: Volute portion 123: Discharge portion
124: Water cutter

Claims (6)

An impeller 110 configured to have a plurality of vanes 111 formed on both sides of the main plate 112 so as to flow fluid from both sides to impart velocity energy to the fluid; And a casing 120 having a discharging portion 123 for guiding the fluid that has passed through the volute portion 122 to the outside In the double suction pump,
Further comprising a water cutter (124) formed in the casing (120) so as to be positioned in a boundary region between the volute portion (122) and the discharge portion (123)
The water cutter shape line L1 formed at the end of the water cutter 124 is not parallel to the vane shape line L2 formed by the end of the vane 111, Shaped structure having two angles of inclination so as to have a predetermined inclination to the impeller side with reference to a reference line VL having a parallel structure with an angle of less than 180 DEG,
Wherein the vane (111) formed on one side surface of the main plate (112) of the impeller (110) and the vane (111) formed on the other side surface of the main plate have staggered arrangement structures. delete delete delete delete delete

Images