KR102046318B1 - Submersible pump efficiency compensation system using spacer - Google Patents

Abstract

The present invention relates to a submersible pump efficiency compensation system using a spacer. The submersible pump efficiency compensation system using a spacer comprises: an upper casing (10); a lower casing (20) coupled to the upper casing (10) by a bolt (B); a wear ring (30) mounted on an inner circumferential surface of the lower casing (20), wherein an inner diameter thereof becomes narrower towards a lower end of the lower casing (20); an impeller (40) connected and installed on the upper casing (10) to be positioned in the lower casing (20); and a spacer (50) installed between the upper casing (10) and the lower casing (20). The spacer (50) includes: a main body unit (52) having a bolt hole (H1) penetrated by the bolt (B); and a gap adjustment unit (54) which is inserted and coupled between the main body unit (52) and the upper casing (10), and adjusts a gap between the wear ring (30) and the impeller (40) by a thickness change. Accordingly, the functionality and usability of the submersible pump efficiency compensation system using the spacer can be improved.

Description

Submersible Pump Efficiency Compensation System Using Spacer {SUBMERSIBLE PUMP EFFICIENCY COMPENSATION SYSTEM USING SPACER}

The present invention relates to an underwater pump efficiency correction system using a spacer, and more particularly, to an underwater pump efficiency correction system using a spacer that can correct the efficiency of the underwater pump by adjusting the gap between the wear ring and the impeller through the spacer. will be.

In general, a pump is a machine for transporting a liquid or gaseous fluid through a tube by a pressure action, or pumping a fluid in a low pressure vessel into a high pressure vessel through the tube.

Such pumps are classified into various types according to their use or place of use.

In particular, submersible pumps are electric pumps that operate in water, and the demand is gradually increasing.

Conventional submersible pumps, as shown in Figure 1, the lower casing (1); A wear ring 2 mounted on an inner circumferential surface of the lower casing 1 and having an inner diameter smaller toward the lower end of the lower casing 1; An impeller 3 rotatably disposed in the lower casing 1; An upper casing 4 engaged with the lower casing 1; And a spacer 5 inserted between the lower casing 1 and the upper casing 4.

When the spacer 5 increases the gap with the impeller 3 due to the wear of the wear ring 2, the spacer 5 narrows the gap between the wear ring 2 and the impeller 3 by changing its thickness to correct the efficiency of the submersible pump. will be.

An underwater pump having such a configuration is disclosed in Korean Patent Publication No. 10-1453972.

However, such a submersible pump has a problem in that it is difficult and complicated to adjust the gap between the wear ring 2 and the impeller 3, and accordingly, the economic cost is high.

That is, in order to adjust the gap between the wear ring 2 and the impeller 3, the coupling state of the lower casing 1 and the upper casing 4 is completely released to remove the spacer 5 installed therebetween, and then The spacer 5 is re-installed between the lower casing 1 and the upper casing 4 in a state where the thickness of the spacer 5 is properly adjusted through cutting.

This, in turn, results in a relatively low functionality and usability of the submersible pump.

The present invention has been made to solve the above problems, the problem to be solved in the present invention is to provide a submersible pump efficiency correction system using a spacer that can easily and efficiently adjust the gap between the wear ring and the impeller There is.

In order to solve the above problems, an underwater pump efficiency correction system using a spacer according to the present invention, the upper casing; A lower casing that is bolted to the upper casing; A wear ring mounted on an inner circumferential surface of the lower casing and having an inner diameter narrowed toward a lower end of the lower casing; An impeller connected to the upper casing and positioned inside the lower casing; And a spacer disposed between the upper casing and the lower casing, wherein the spacer includes a main body portion having a bolt hole through which the bolt passes; It is technically characterized in that it is fitted between the body portion and the upper casing, the gap adjusting portion for adjusting the gap between the wear ring and the impeller through a thickness change.

Underwater pump efficiency correction system using a spacer according to the present invention can easily and efficiently adjust the gap between the wear ring and the impeller without disassembling the upper and lower casing through the height adjusting portion of the spacer.

Therefore, maintenance of the submersible pump is easy and maintenance costs can be reduced.

Therefore, the functionality and usability of the underwater pump efficiency correction system using a spacer can be improved.

1 is a partial cross-sectional view showing a conventional submersible pump,
2 is a partial cross-sectional view of an underwater pump efficiency correction system using a spacer according to the present invention;
3 is a plan view showing a main body of the spacer of the submersible pump efficiency correction system using the spacer according to the present invention;
4 is a cross-sectional view showing a main body of the spacer of the submersible pump efficiency correction system using the spacer according to the present invention;
5 is a plan view showing a spacer of the spacer of the underwater pump efficiency correction system using a spacer according to the present invention,
Figure 6 (a), (b) is a cross-sectional view showing the spacer of the spacer of the submersible pump efficiency correction system using the spacer according to the present invention,
7 is a cross-sectional view showing another embodiment of a wear ring of the underwater pump efficiency correction system using a spacer according to the present invention;
(A), (b) is a cross-sectional view showing another embodiment of the main body of the spacer of the submersible pump efficiency correction system using the spacer according to the present invention;
9 is a cross-sectional view showing another embodiment of the spacer of the spacer of the submersible pump efficiency correction system using the spacer according to the present invention;
10 is a state diagram illustrating a process of adjusting a space between a wear ring and an impeller of a submersible pump efficiency correction system using a spacer according to the present invention.

Hereinafter, a submersible pump efficiency correction system using a spacer according to the present invention will be described with reference to the accompanying drawings.

As shown in Figures 2 to 6, the submersible pump efficiency correction system using a spacer according to the present invention comprises an upper casing (10); A lower casing 20 coupled with the upper casing 10; Wear ring 30 mounted on the inner peripheral surface of the lower casing (20); An impeller 40 connected to the upper casing 10; It comprises a spacer 50 is installed between the upper casing 10 and the lower casing 20.

The upper casing 10 and the lower casing 20 are communicatively coupled, and a bolt B is used as the coupling means.

The upper and lower casings 10 and 20 are made of a material having excellent physical properties in water.

The wear ring 30 is for precisely maintaining the gap with the impeller 40 and is made of a metal or synthetic resin material having excellent physical properties such as durability and corrosion resistance.

The wear ring 30 is for preventing the fluid on the discharge side of the impeller 40 from flowing back to the suction side.

In particular, the wear ring 30 has a cylindrical structure, the inner diameter is gradually narrowed toward the lower end of the lower casing 20, the wear ring through the change in the installation position of the impeller 40 by the configuration features of the wear ring 30 ( 30) and the gap between the impeller 40 can be adjusted.

Meanwhile, the wear ring 30 may additionally form the flow preventing protrusions 32 on the outer circumferential surface at regular intervals to maintain the installation state on the lower casing 20 as shown in FIG. 7. At this time, a friction coating layer for providing a frictional force may be provided on the contact surface of the flow preventing protrusion 32 which is in direct contact with the inner circumferential surface of the lower casing 20.

The impeller 40 serves to suck water in the water into the lower casing 20 by the rotation operation.

The impeller 40 is interlocked with the upper casing 10 and is located inside the lower casing 20.

The spacer 50 is made of a metal material having excellent durability, water resistance, and the like, and may be selectively applied to various kinds of known materials having excellent physical properties.

Such a spacer 50 is for adjusting the gap between the wear ring 30 and the impeller 40. That is, the spacer 50 moves the position of the wear ring 30 and the impeller by moving the position of the impeller 40 connected to the upper casing 10 through the thickness change when the wear ring 30 wears due to the operation of the submersible pump. It serves to adjust the gap between the 40.

The spacer 50 includes a main body portion 52 in which a bolt hole H1 through which the bolt B penetrates is formed; It is composed of a gap adjusting portion 54 is fitted between the body portion 52 and the upper casing (10).

The body part 52 is positioned between the lower casing 20 and the gap adjusting part 54, and includes a first support 52a on which a bolt hole H1 is formed; It consists of a second support (52b) is bent upward from the inner circumferential surface of the first support (52a) to a predetermined height and completely in contact with the inner surface of the upper casing (10).

The cross sections of the first support 52a and the second support 52b have a substantially '┙' shape.

The first support 52a is formed in a ring shape having a predetermined width, and the bolt B is penetrated.

Like the first support 52a, the second support 52b has a ring shape having a predetermined width. And the O-ring insertion groove (G) is formed on the surface of the second support (52b) in close contact with the inner surface of the upper casing 10, the O-ring insertion groove (G) is inserted into the O-ring 60 for airtight.

In addition, the foreign material removal inclined surface (S) inclined at an angle toward the inner surface of the upper casing 10 is formed at the end of the second support (52b), the foreign material removal inclined surface (S) is a coating layer for preventing adhesion of foreign matter. (Not shown) may be additionally formed. When the downward movement of the upper casing 10 according to the change in the thickness of the gap adjusting portion 54 through the foreign substance removal inclined surface (S), foreign matter on the inner surface of the upper casing 10 may be removed to facilitate the movement.

Spacing adjuster 54 is to adjust the distance between the wear ring 30 and the impeller 40 by moving the position of the impeller 40 with respect to the wear ring 30 through the thickness change by replacement or cutting process. .

It is preferable that a plurality of such gap adjusting portions 54 are disposed between the first support 52a and the upper casing 10.

In particular, the gap adjusting portion 54 is formed with a bolt interference prevention groove 54a of a predetermined depth on one side so as not to interfere with the bolt (B) during the fitting operation. The gap adjusting part 54 has a substantially '⊂' shape, and is made of stainless steel (SUS) material having excellent physical properties such as durability and water resistance.

Although not shown separately in the drawings, shock absorbing pads (not shown) may be additionally installed on the upper and lower surfaces of the gap adjusting part 54 in order to alleviate the impact at the time of external shock.

In the meantime, reference numeral H2 illustrates a bolt hole through which a fixing bolt for fixing the spacer 50 passes.

8 (a) and (b) are cross-sectional views showing another embodiment of the main body of the spacer of the submersible pump efficiency correction system using the spacer according to the present invention, the upper surface of the first support (52a) of the main body 52 A plurality of guide grooves (g) to which the gap adjusting portion 54 is fitted is formed.

By such a guide groove (g), it is possible to easily perform the fitting coupling of the gap adjusting portion 54, as well as to prevent the flow of the gap adjusting portion 54 to maintain a firm and stable coupling state Can be.

Except for the guide groove g described above, the same as the main body 52 described with reference to FIGS. 3 and 4 will not be described in detail.

The process of adjusting the interval between the wear ring 30 and the impeller 40 of the submersible pump efficiency correction system using the spacer described above will be briefly described with reference to FIG. 9.

First, when the space between the wear ring 30 and the impeller 40 is widened and the efficiency of the submersible pump is lowered, the fastening state of the bolt B fastened to the upper casing 10 and the lower casing 20 is partially described. Release to remove the gap adjusting portion 54 is fitted between the body portion 52 and the upper casing (10).

And the upper casing (by re-fastening the bolt (B) in the state sandwiched between the main body 52 and the upper casing 10 is relatively thinner than the removed gap adjusting portion 54. As the 10 moves downward, the impeller 40 is interlocked to narrow the gap between the wear ring 30 and the impeller 40.

10: upper casing 20: lower casing
30: wear ring 40: impeller
50: spacer 52: main body
52a: first support 52b: second support
54: spacing adjusting part 54a: bolt interference prevention groove
60: O-ring B: bolt
S: Foreign material removal slope G: O-ring insert groove

Claims (6)

Upper casing 10;
A lower casing 20 coupled to the upper casing 10 and a bolt B;
A wear ring 30 mounted on an inner circumferential surface of the lower casing 20 and having an inner diameter narrowed toward a lower end of the lower casing 20;
An impeller 40 connected to the upper casing 10 and positioned inside the lower casing 20;
It includes a spacer 50 is installed between the upper casing 10 and the lower casing 20,
The spacer 50 may include a main body portion 52 in which a bolt hole H1 through which the bolt B penetrates is formed; Fitted between the main body 52 and the upper casing 10, it is made of a gap adjusting portion 54 for adjusting the gap between the wear ring 30 and the impeller 40 through a thickness change,
The main body 52,
A ring-shaped first support 52a positioned between the lower casing 20 and the gap adjusting part 54 and in which the bolt hole H1 is formed; Underwater pump efficiency correction system using a spacer, characterized in that consisting of a second support (52b) is bent upward from the inner peripheral surface of the first support (52a) to be in close contact with the inner surface of the upper casing (10).
delete The method according to claim 1,
Submersible pump efficiency correction system using a spacer, characterized in that the foreign material removal inclined surface (S) is formed at the end of the second support (52b).
The method according to claim 1,
O-ring insertion groove (G) is formed in the second support (52b), O-ring 60 is inserted into the O-ring insertion groove (G) Submersible pump efficiency correction system using a spacer, characterized in that.
The method according to claim 1,
The gap adjusting unit (54) is a plurality of submersible pump efficiency correction system using a spacer, characterized in that disposed between the plurality of the first support (52a) and the upper casing (10).
The method according to claim 1,
Underwater pump efficiency correction system using a spacer, characterized in that the bolt interference prevention groove (54a) is formed on one side of the gap adjusting portion (54).

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