KR20150112243A - Double suction type centrifugal pump - Google Patents

Abstract

The present invention relates to a double suction centrifugal pump. The purpose of the present invention is to provide a double suction centrifugal pump which forms a pressure chamber by using the space formed between an impeller and a pumping chamber, makes internal pressure of the pressure chamber to be formed an equal pressure condition with the pressure of a discharged fluid by charging a part of the fluid pressurize by the impeller in the pressure chamber, prevents an eddy from being generated around an outlet of the impeller, and induces stable rotation of the impeller since the fluid charged inside the pressure chamber supports the rotation of the impeller. In the double suction centrifugal pump comprising: the impeller wherein an inlet port for intaking fluid is formed on both side units and multiple wings for pressurizing the fluid taken in through the inlet port are included in the inner side; a pump case including the pumping chamber to accommodate the impeller in the inner side; and a rotary shaft to rotate the impeller by being combined with the impeller, the present invention for the same is to provide a double suction centrifugal pump which has a ring-shaped structure extended along the circumference of the impeller between the outer side of the impeller and the inner side of the pumping chamber and forms a pressure chamber wherein the fluid pressurized by the rotation of the impeller is charged.

Description

Double suction type centrifugal pump < RTI ID = 0.0 >

More particularly, the present invention relates to a double suction type centrifugal pump. More particularly, the present invention relates to a double suction type centrifugal pump. More particularly, the present invention relates to a double suction type centrifugal pump, So that stable rotation can be realized.

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

Such a centrifugal pump is divided into a single suction centrifugal pump and a double suction centrifugal pump according to a method of sucking fluid.

The single suction centrifugal pump is a centrifugal pump having a structure in which a fluid is sucked and discharged only from one side of the impeller. It is difficult to realize a pump system of a lifting pump due to a small suction amount of the fluid. Further, There is a problem that an excessive thrust load acts on the bearing to be supported and the bearing is easily damaged.

On the other hand, the double suction type centrifugal pump is a centrifugal pump having a structure for sucking fluid from both sides of the impeller. Since the suction amount of the fluid is larger than that of the single suction type centrifugal pump, the pump system of the high- The thrust load acting on the rotating shaft, the impeller and the bearing is small.

FIG. 1 is a cross-sectional view showing the structure of a conventional double suction type centrifugal pump, and FIG. 2 is a detail view showing an enlarged view of a discharge side of an impeller provided in a conventional double suction type centrifugal pump.

The conventional double suction type centrifugal pump has an impeller 10 accommodated in a pump case 20 and a rotating shaft 31 installed to penetrate the pump case 20 is coupled with the impeller 10, Is connected to an unillustrated motor and rotates while rotating the impeller.

In order to pump the fluid while minimizing the drop in pumping efficiency during rotation of the impeller, it is desirable to minimize the gap between the suction port of the impeller and the pump case. Of course, if the gap between the suction port of the impeller and the pump case can be completely closed, the pumping efficiency can be optimized. However, in this case, excessive frictional resistance is generated between the impeller and the pump case during rotation of the impeller, So that an artificial gap within an allowable range is formed between the inlet of the impeller and the pump case.

Meanwhile, the pump case is formed of a three-dimensional shape in which various curved surfaces are combined to effectively flow the fluid. Since the pump case is not easily manufactured by machining, the pump case is generally manufactured as a casting.

As is well known, since the precision of casting production is significantly lower than the precision of machining, it is not possible to form a gap having a required precision between the inlet of the impeller and the pump case through the casting, And the inside of the pump case is mechanically machined to install the wear ring 40.

As a result, in the case of the conventional double suction type centrifugal pump, the remaining portion except for the portion where the wear ring is installed has precision in casting production. In order to prevent a decrease in the pumping efficiency, the gap between the pump case and the impeller is narrowed , There is a fear that the pump case may come into contact with the impeller when the impeller rotates.

Therefore, conventionally, as shown in Figs. 1 and 2, a wear ring is disposed in the vicinity of the inlet of the impeller to form a minute gap between the inlet of the impeller and the pump case, while the accuracy of casting is considered So that a sufficient space S is formed between the impeller and the pump case.

However, a part of the discharge fluid flows into the space S formed between the pump case and the impeller and vortices are generated around the discharge port of the impeller. Such vortices interfere with the flow of the discharge fluid, In addition, there is a problem that vibration or noise of the impeller is generated.

Public Utility Model Publication No. 1999-002230 (published on 25.01.1999)

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 pressure chamber which is formed by using a space formed between an impeller and a pumping chamber, It is possible to prevent a vortex from occurring around the discharge port of the impeller by making the pressure inside the pressure chamber equal to the pressure of the discharge fluid by filling the pressure chamber and the fluid filled in the pressure chamber supports the rotation of the impeller And to provide a double suction type centrifugal pump capable of inducing stable rotation of the impeller.

According to an aspect of the present invention, there is provided a suction device for a fluid, comprising: a suction port for sucking fluid; and a plurality of blades for pressurizing the fluid introduced through the suction port, An impeller having an inside thereof; And a pump case having therein a pumping chamber for accommodating the impeller therein; And a rotating shaft coupled to the impeller and rotating the impeller. The centrifugal pump has an annular structure extending between the outer surface of the impeller and the inner surface of the pumping chamber and extending along the circumference of the impeller, And a pressure chamber in which a fluid to be pressurized is filled is formed.

Meanwhile, in the double suction type centrifugal pump, the pressure chamber may include: an outer surface of the impeller; an inner surface of the pumping chamber facing the outer surface; a first wear ring installed in the pump case to be positioned on the suction port side of the impeller; And a second wear ring provided on the pump case so as to be positioned on the discharge port side of the impeller.

On the other hand, in the double suction centrifugal pump, at least one flow hole for allowing a part of the fluid pressurized by the rotation of the impeller to move to the pressure chamber may be further formed on the outer wall forming the outer surface.

According to the present invention having the above-described features, it is possible to prevent the vortex from being generated around the discharge port of the impeller to prevent the pumping efficiency from being lowered, and the fluid filled in the pressure chamber stably supports the rotation of the impeller Thereby providing a stable rotating environment of the impeller, thereby effectively preventing noise or vibration from being generated.

1 is a sectional view showing the structure of a conventional double suction type centrifugal pump,
2 is an enlarged view showing a discharge side of an impeller provided in a conventional double suction type centrifugal pump,
FIG. 3 is a sectional view showing the structure of a double suction type centrifugal pump according to a preferred embodiment of the present invention,
FIG. 4 is a sectional view showing a detailed structure of an impeller and a pressure chamber according to the present invention,

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.

FIG. 3 is a cross-sectional view showing the structure of a double suction type centrifugal pump according to a preferred embodiment of the present invention, and FIG. 4 is a sectional view showing a detailed structure of an impeller and a pressure chamber according to the present invention.

The double suction type centrifugal pump according to the present invention forms a pressure chamber P using a space S (shown in FIG. 1) formed between the outer surface 113a of the impeller 110 and the pump case 120 , An environment composition for stable rotation of the impeller 110 by filling a part of the discharge fluid in the pressure chamber P and a feature of preventing vortices from occurring around the discharge port of the impeller 110.

A double suction centrifugal pump having such characteristics is composed of an impeller 110, a pump case 120, and a rotating shaft 130.

The rotation shaft 130 has a structure to rotate the impeller 110 while being rotated by driving the motor. The structure of the rotation shaft 130 is similar to that of the conventional double suction type centrifugal pump As shown in FIG.

The impeller 110 is composed of a hub 111, a blade 112, and an outer wall 113.

The hub 111 is coupled to the rotary shaft 130 and has a cylindrical structure. A central partition 1111 is provided around the center of the hub 111. At this time, the central partition 1111 protrudes radially from the outer surface of the hub 111 with the hub 111 as the center.

The vanes 112 are connected to the central partition 1111 and the hub 111 and rotate together to pressurize the fluid. The vanes 112 are formed on the both sides of the central partition 1111.

The outer wall 113 is disposed at a position spaced away from the center partition 1111 in the right and left of the central partition 1111 and connected to the plurality of vanes 112. [ . The outer wall 113 is formed by combining a conical shape and a ring shape, and is connected to a plurality of blades to form a flow path through which the fluid flows, and the inlet 114 is formed at both side portions of the impeller 110.

For the convenience of explanation, the hub 111, the blade 112 and the outer wall 113 have been separately described. However, the actual double suction type impeller includes a single inlet 114 and a half of the impeller After that, the separately manufactured two halves are coupled to each other to produce a completed double suction type impeller, and the impeller of the present invention can also be manufactured by a conventional method.

In the impeller 110 according to the present invention, not only a stepped portion 116 facing the wear ring is formed on the outer surface of the suction port 114 but also a stepped portion 117 facing the wear ring is formed on the outer surface of the discharge port 115 side There is a difference from the conventional impeller in the formed point.

The outer wall 113 is provided with one or more flow holes (not shown) for allowing a part of the fluid pressurized by the rotation of the impeller 110 to flow into the pressure chamber P formed between the impeller 110 and the pump case 120 118 are further formed.

The pump case 120 includes an inlet (not shown) for receiving the impeller 110 therein and allowing the fluid to flow into the pump case 120, (Not shown) through which the pressurized fluid is discharged.

The suction port 114 formed on both sides of the impeller 110 is exposed to the inside of the pump case 120 and the discharge port 115 of the impeller 110 is connected to the pump case 120, A pumping chamber C for accommodating the impeller 110 is formed so as to be positioned at a position corresponding to a discharge port formed in the impeller 110. A pressure chamber C is formed between the inner surface 120a of the pumping chamber C and the outer surface 113a of the impeller 110, (P).

More specifically, the pressure chamber P includes an outer surface 113a of the outer wall 113 of the impeller 110 and an inner surface 120a formed in the pumping chamber C to face the outer surface 113a of the outer wall 113 A first wear ring 141 installed on the pump case 120 so as to be located on the side of the suction port 114 of the impeller 110 and a second wear ring 141 disposed on the side of the discharge port 115 of the impeller 110, And a second wear ring 142 installed on the first rotating shaft 120, and is configured to have an annular structure with the rotating shaft 130 as a central axis.

The pump case 120 may have a structure in which the corresponding portion of the pump case 120 protrudes to a position close to the stepped portion 117 formed on the side of the discharge port 115 of the impeller 110 in place of the second wear ring 142, The pump case 120 or the impeller 110 may be formed by direct contact between the pump case 120 and the impeller 110. In this case, It is preferable that the second wear ring 142 is installed in the pump case 120 to constitute the pressure chamber P. [

For reference, the first wear ring 141 and the second wear ring 142 may be fixed to the pump case 120 by bolts.

The pressure chambers P having the above structure are formed on both left and right sides of the impeller 110, respectively.

The operation and effect of the double suction type centrifugal pump of the present invention constituted as described above are as follows.

The double suction type centrifugal pump according to the present invention is also similar to the conventional double suction type centrifugal pump in that the rotational force generated by the driving of the motor not shown is transmitted to the impeller 110 through the rotary shaft 130, And the fluid is simultaneously introduced into the suction port 114 formed on both side portions of the impeller 110 by the rotation of the impeller 110, thereby pumping the fluid.

A part of the fluid flowing through the flow path formed inside the impeller 110 in the process of pumping the fluid as described above flows into the inside of the pressure chamber P through the flow hole 118 formed in the outer wall 113 of the impeller 110 So that the internal pressure of the pressure chamber P is kept equal to the pressure of the discharge fluid discharged from the impeller 110.

The pressure chambers P are uniformly formed on both side portions of the impeller 110 and the fluid filled in the pressure chambers P functions as a bearing so that the inlets formed on both sides of the impeller 110 It is possible to induce stable rotation of the impeller 110 even under unstable rotating conditions in which the amount of fluid flowing through the impeller 110 is different.

A part of the discharge fluid exiting the discharge port 115 is discharged to the outer side wall 113 and the pump case 101 through the discharge port 115 of the impeller 110, 120, thereby preventing the formation of vortices and effectively pumping the fluid without pressure loss of the fluid.

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
P: pressure chamber 110: impeller
111: hub 1111: central bulkhead
112: wing 113: outer wall
113a: outer surface 114: inlet
115: Outlet port 118: Flow hole
120: pump case 120a: inner surface
130:
141: first wear ring 142: second wear ring

Claims (3)

An impeller 110 formed on both side portions of a suction port 114 for suctioning fluids and having a plurality of vanes 112 for pressurizing fluids introduced through the suction ports 114; And a pump case (120) having a pumping chamber (C) for accommodating the impeller (110) therein; And a rotating shaft (130) coupled to the impeller (110) and rotating the impeller, the centrifugal pump comprising:
Between the outer surface 113a of the impeller 110 and the inner surface 120a of the pumping chamber C is formed an annular structure extending along the circumference of the impeller 110 and a fluid pressurized by the rotation of the impeller 110 And a pressure chamber (P) to be filled is formed. The method according to claim 1,
The pressure chamber P includes an outer surface 113a of the impeller 110, an inner surface 120a of the pumping chamber C facing the outer surface 113a, a suction port 114 of the impeller 110, And a second wear ring 142 installed on the pump case 120 so as to be positioned on the side of the discharge port 115 of the impeller 110 Wherein the centrifugal pump is formed in a cylindrical shape. The method according to claim 1,
One or more flow holes 118 are formed in the outer wall 113 forming the outer surface 113a to allow a part of the fluid to be pressurized by the rotation of the impeller 110 to move to the pressure chamber P. Suction type centrifugal pump.

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