KR102653746B1 - Zinc anod unit for submersible pumps with improved corrosion resistance and maintainability - Google Patents

Abstract

The present invention relates to a zinc anode unit for a submersible pump.
The purpose of the present invention is to form a zinc anode unit composed of independent parts consisting of an insertion pipe and a blocking guide plate, and to enable it to be used by selectively attaching and detaching the inner diameter surface of the suction pipe of a submersible pump, thereby providing a galvanic corrosion prevention function and suction. The aim is to provide a zinc anode unit for a submersible pump with improved corrosion resistance and maintainability to prevent foreign substances contained in the water from entering the submersible pump through the suction pipe.
Therefore, the specific means of the present invention for achieving the above object are;
In a submersible pump consisting of a drive unit, a chamber unit, an impeller unit, a suction pipe, and a discharge pipe, a zinc anode unit is further combined and formed on the inner diameter surface of the suction pipe with an insertable detachable structure;
The zinc anode unit is achieved by forming an insertion pipe forming a conical pipe structure and a plurality of blocking guide plates integrally coupled at regular intervals around the inner diameter surface of the insertion pipe.
And, it is achieved by molding the zinc anode unit formed by the insertion installation pipe and the blocking guide plate from a zinc steel sheet material.

Description

Zinc anode unit for submersible pumps with improved corrosion resistance and maintainability}

The present invention relates to a zinc anode unit for a submersible pump, and more specifically, to a device that transports or drains water by submersible pumping, such as a submersible pump, by installing a zinc anode unit in the submersible pump to prevent corrosion. A submersible pump with improved corrosion resistance and maintainability by minimizing the zinc anode unit's blocking guide plate as an independent part and making it easy to attach, detach, and replace as individual components on the inner wall of the suction pipe of the submersible pump. This is about the zinc anode unit.

A submersible pump is a device used to smoothly and effectively supply and drain water and control water levels through electrical pumping in various industrial sites such as swimming pools, fish farms, flooded sites, agricultural sites, and construction sites.

Types of submersible pumps are largely classified into lifting pumps, centrifugal pumps, and fluid pumps depending on the specific purpose or working environment.

Here, a lift pump is a type of pump that moves water by rotor rotation and is mainly used for work requiring small flow rates and high positive pressure. A centrifugal pump is a type of pump that suctions and pushes water using rotating centrifugal force. It is mainly used to process large flow rates. A fluid pump is a type of pump that moves water through fluid motion between the rotor and stator, and is mainly used for tasks that handle high flow rates and pressures.

On the other hand, although submersible pumps are classified into various types as described above depending on the specific purpose or working environment, the basic operating principles and methods, and core component configurations can be said to be the same or similar.

For example, regardless of their type, submersible pumps include a drive unit that transmits pumping power, a water chamber that performs pumping action by pressure changes caused by the operation of the drive unit, an impeller unit that generates and compresses the movement of water, and a water pump. For example, the basic configuration includes a suction pipe for suction and a discharge pipe for moving the sucked water and discharging it to the outside.

Therefore, these submersible pumps pump various types of liquid media in a state immersed in various types of liquid media, such as general water, waste polluted water, seawater, etc., depending on the field situation in which they are used, and also provide variable flow rate shock (change) of the pumped liquid media. ) has use characteristics that are directly exposed to

However, the conventional submersible pump has a suction pipe made of a material such as carbon steel, which is vulnerable to corrosion, and there is a problem in that the service life of the product is shortened due to a decrease in corrosion resistance and wear resistance, especially due to galvanic corrosion.

Here, galvanic corrosion refers to a phenomenon in which the movement of electrons occurs due to the presence of a potential difference when different double metals come into contact with a liquid medium, and at this time, the dislocated metal is corrosion-resistant, while the active potential metal accelerates corrosion. .

Additionally, in submersible pumps, the suction pipe does not have a separate means to effectively block the inflow of foreign substances exceeding a certain volume contained in the suctioned water, such as gravel, tree branches, sludge aggregates, and various other debris. There is a problem that the submersible pump frequently becomes clogged and malfunctions due to incoming foreign substances.

Republic of Korea Patent Registration No. 1647422 (registered on 2016.08.04.) Republic of Korea Patent Registration No. 1562027 (registered on October 14, 2015)

The present invention was created to solve general problems occurring with conventional submersible pumps, such as galvanic corrosion.

The purpose of the present invention is to form a zinc anode unit composed of independent parts consisting of an insertion installation pipe and a blocking guide plate, and to enable the zinc anode unit formed as such to be used by attaching to the inner diameter surface of the suction pipe of a submersible pump with a selective attachment and detachment structure. By doing so, we provide a zinc anode unit for a submersible pump that has improved corrosion resistance and maintainability to prevent foreign substances contained in the water being sucked from entering the submersible pump through the suction pipe, in addition to the galvanic corrosion prevention function.

The purpose of the present invention is to mold a zinc anode unit, which is formed as an independent part, from a zinc material with excellent corrosion resistance, corrosion resistance, and processability, so that it can be used for various types of liquid media such as general water, waste polluted water, and seawater, and for variable flow rates of these liquid media. The aim is to provide a zinc anode unit for a submersible pump with improved corrosion resistance and maintainability that can significantly extend the service life by minimizing corrosion or erosion due to shock (change), such as galvanic corrosion.

The purpose of the present invention is to divide and form the blocking guide plate forming the zinc anode unit into separate independent parts, and to individually install the divided blocking guide plate on the inner diameter surface of the suction pipe of the submersible pump, for example, to provide a structure for detachment and attachment by fastening means. The aim is to provide a zinc anode unit for a submersible pump with improved corrosion resistance and maintainability that can greatly improve the convenience, speed, and economic efficiency of maintenance work by enabling exchange.

Therefore, the specific means of the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention to achieve the above object are;

In a submersible pump consisting of a drive unit, a chamber unit, an impeller unit, a suction pipe, and a discharge pipe, a zinc anode unit is further combined and formed on the inner diameter surface of the suction pipe with an insertable detachable structure;

The zinc anode unit is achieved by forming an insertion pipe forming a conical pipe structure and a plurality of blocking guide plates integrally coupled at regular intervals around the inner diameter surface of the insertion pipe.

And, it is achieved by molding the zinc anode unit formed by the insertion installation pipe and the blocking guide plate from a zinc steel sheet material.

Above, the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention forms a unit of a zinc anode unit composed of independent parts consisting of an insertion installation pipe and a blocking guide plate, and the zinc anode thus formed The node unit can be used in combination with a selective attachment and detachment structure on the inner diameter surface of the suction pipe of a submersible pump. This provides the effect of preventing foreign substances from entering the submersible pump through the suction pipe in addition to the galvanic corrosion prevention function.

In addition, the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention is made of a zinc material with excellent corrosion resistance, corrosion resistance, and processability, so that it can be used in various types of liquid media. Easily corroded or eroded by the variable flow rate shock (change) of the liquid medium is minimized, which has the effect of extending the product's service life.

Alternatively, the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention is formed by dividing the blocking guide plate forming the zinc anode unit into an independent part, and attaching the divided blocking guide plate to the submersible pump. It is designed to be individually installed on the inner diameter of the suction pipe so that it can be detached, attached, and exchanged. This improves the convenience, speed, and economic efficiency of maintenance work, providing very useful expected effects.

Figure 1 is a partially exploded configuration diagram of a zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention.
Figure 2 is a cross-sectional view of the enlarged main part of the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention.
Figure 3 is a flat cross-sectional view of the main part of the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention.
Figure 4 is an example of another combined configuration state of the suction pipe and zinc anode unit applied to the present invention.
Figure 5 is a cross-sectional diagram of this embodiment of the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention.
Figure 6 is an enlarged cross-sectional view of the bolt unit applied to this embodiment of the present invention

Hereinafter, the configuration of a preferred embodiment of a zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention will be described in detail based on the attached drawings.

Looking at the schematic configuration of the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention with reference to the attached drawings, it consists of a drive unit 100 and a chamber unit ( 200), a submersible pump including an impeller unit 300, a suction pipe 400, and a discharge pipe 500, and a zinc anode unit (1) coupled to the suction pipe 400 of the submersible pump. .

In the present invention, the drive unit 100 consisting of the submersible pump is a power generation means that accommodates and installs an electric motor 101 and provides pumping power by the driving action of the installed electric motor 101.

This drive unit 100 is no different from the configuration of a known drive unit applied to a general submersible pump. Therefore, detailed descriptions of specific mechanical components, drawings, and operating functions of the drive unit 100 will be omitted below.

In the present invention, the chamber unit 200 composed of the submersible pump is a means of receiving pumping power from the above-described drive unit 100 and performing a pumping action by a pressure change due to the received pumping power.

This chamfer unit 200 is not different from the configuration of a known chamber unit applied to a general submersible pump. Therefore, detailed descriptions of specific mechanical components, drawings, and operating functions of the chamber unit 200 will be omitted below.

In the present invention, the impeller unit 300 consisting of the submersible pump is a means for generating and compressing the movement of water sucked by the rotation of the impeller blades.

This impeller unit 300 is not different from the configuration of a known impeller unit applied to a general submersible pump. Therefore, detailed descriptions of specific mechanical components, drawings, and operating functions of the impeller unit 300 will be omitted below.

In the present invention, the suction pipe 400 comprised of the submersible pump is a type of piping configuration that suctions water to be pumped and transported. In applying this suction pipe 400 to the present invention, as shown in FIG. 2, the inner diameter surface of the suction pipe 400 is formed in a configuration in which the inner diameter surface of the suction pipe 400 gradually widens toward the bottom, for example, a conical pipe structure, and such suction pipe 400 It is preferable to arrange a plurality of fastening holes 401 having a female thread structure as shown in FIG. 2 around the bottom surface.

Alternatively, as another embodiment of the suction pipe 400 applied to the present invention, a fixed sliding fastening groove (H) is provided around the lower outer diameter surface of the suction pipe 400 forming the conical piping structure as shown in FIG. A flange 402 may be formed.

In the present invention, the discharge pipe 500 comprised of the submersible pump is a type of piping configuration that guides and transports water sucked through the above-mentioned suction pipe 400 so that it can be discharged to the outside.

This discharge pipe 500 is not different from the well-known discharge pipe configuration applied to a general submersible pump. Therefore, detailed descriptions of specific mechanical components, drawings, and operating functions of the discharge pipe 500 will be omitted below.

Meanwhile, in the present invention, the zinc anode unit (1) coupled to the suction pipe (400) of the submersible pump is such that different dissimilar metals come into contact with the liquid medium during the process of sucking water through the above-described suction pipe (400). In addition to the function of preventing corrosion phenomena that occur due to corrosion, such as galvanic corrosion, it also prevents the inflow of foreign substances exceeding a certain volume contained in the inhaled water, such as gravel, tree branches, sludge aggregates, and other various types of waste. It is the main core component of complex functions.

This zinc anode unit 1 forms an insertion installation pipe 11 of a conical piping structure whose diameter gradually widens toward the lower surface as shown in Figures 1 and 2, and the insertion installation pipe ( 11) It is desirable to form a configuration in which a plurality of blocking guide plates 12 are integrated and combined at regular and repetitive intervals around the inner diameter surface.

And, in particular, the zinc anode unit (1) formed of the insertion installation pipe (11) and the blocking guide plate (12) is made of all components of the zinc anode unit (1) of a specified material composition, for example, a zinc steel sheet material. It is desirable to mold it limited to .

At this time, in the zinc anode unit (1), the insertion installation pipe (11) further forms a fastening flange (111) with a plurality of fastening assembly holes (P) as shown in FIG. 2 around its lower surface. You can.

Alternatively, the zinc anode unit 1 is another embodiment of the insertion tube 11, and is provided with a sliding fastener (D) around the lower outer diameter surface of the insertion tube 11 as shown in FIG. ) can form a detachable flange 112 provided.

Therefore, looking at the coupling relationship of the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention, which consists of a series of configurations as described above, the following is provided.

First, a well-known submersible pump including a drive unit 100, a chamber unit 200, an impeller unit 300, a suction pipe 400, and an discharge pipe 500 is prepared.

Then, in the submersible pump, the zinc anode unit 1 is coupled to the inner diameter surface of the suction pipe 400 in an insertable structure that can be attached and detached as shown in FIG. 2.

At this time, in the case where the fastening holes 401 are arranged around the lower surface of the suction pipe 400 to which the zinc anode unit 1 is coupled, the zinc anode with the fastening flange 111 is formed as shown in FIG. 2. The unit (1) is inserted and coupled to the suction pipe (400), and the suction pipe is fastened with a bolt (B) through the fastening hole (401) formed by the suction pipe (400) and the fastening assembly hole (P) provided by the fastening flange (111). Provides fixing force to the joint area between (400) and the zinc anode unit (1).

Alternatively, in the case where a fixing flange 402 with a sliding fastening groove (H) is formed around the lower outer diameter surface of the suction pipe 400 to which the zinc anode unit 1 is coupled, it can be detached as shown in FIG. 4. The zinc anode unit (1) on which the flange (112) is formed is inserted and coupled to the suction pipe (400), and the sliding fastening groove (H) formed by the suction pipe (400) and the sliding fastener (D) provided by the detachable flange (112). is caught using a sliding insertion structure to provide fixing force to the joint portion of the suction pipe 400 and the zinc anode unit 1.

Accordingly, the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention has a structure of selective attachment and detachment to the inner diameter surface of the suction pipe 400 of the submersible pump by forming the zinc anode unit (1) as an independent component. By allowing it to be assembled and used, the installation of the zinc anode unit (1) is made more quickly and conveniently, and the operating function that increases the series of handling efficiency is accordingly given.

In addition, the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention is a zinc anode unit using a material known to have excellent corrosion resistance, corrosion resistance, and processability, such as a zinc steel sheet material. By forming (1), it is given the function of minimizing the occurrence of galvanic corrosion due to the type of liquid medium being pumped or the variable flow velocity shock (change) of the liquid medium.

Meanwhile, Figure 5 is a cross-sectional diagram of this embodiment of a zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention, and Figure 6 is an enlarged configuration of a bolt unit applied to this embodiment of the present invention. Shows a cross-sectional view.

The present invention as this embodiment, in the configuration of the above-described embodiment, has a plurality of horizontally penetrating guide plate assembly holes 403 as shown in FIG. 5 in a regular and repetitive spacing arrangement around the central portion of the outer diameter of the suction pipe 400. It is preferable to form an auxiliary fastening hole 404 around the outer surface of the guide plate assembly hole 403.

In addition, the present invention as this embodiment has an assembly nut member 131 protruding in an integrated structure on one outer surface as shown in FIG. 5 of the zinc anode unit 1 in the configuration of the above-described embodiment. It is desirable to form only the detachment guide plate 13 in the form of an independent divided part.

Accordingly, the combination relationship of this embodiment of the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention, which consists of a series of configurations as described above, is as follows.

First, the detachment guide plate 13 is inserted into the inner diameter surface of the suction pipe 400, and then the guide plate assembly hole 403 formed through the suction pipe 400 and the assembly nut member 131 formed by the detachment guide plate 13 are aligned. Adhere closely.

Next, the detachment guide plate 13 is arranged at regular and repetitive intervals around the inner diameter surface of the suction pipe 400 by fastening the bolt unit 2 through the closely adhered guide plate assembly hole 403 and the assembly nut member 131. By being fixedly coupled, this embodiment of the zinc anode unit for a submersible pump with improved corrosion resistance and maintainability according to the present invention is achieved.

At this time, the bolt unit (2), which couples and secures the detachment guide plate (13) around the inner diameter surface of the suction pipe (400), has a watertight protruding extension structure in which the main fastening bolt (211) is coupled to the central portion, as shown in FIG. An insertion hole 21 is formed, and a watertight flange 22 to which an auxiliary fastening bolt 221 is coupled is formed around the outer surface of the watertight insertion hole 21. Therefore, the bolt unit 2 of this configuration functions to prevent water pumped from leaking into the joint area between the suction pipe 400 and the detachment guide plate 13.

Accordingly, in this embodiment of the present invention, the zinc anode unit 1 is formed with divided individual blocking guide plates 13, and these individually configured blocking guide plates 13 are individually removed from the inner diameter surface of the suction pipe 400. , By allowing it to be used by exchanging and installing with an attachment structure, it is given an operational function that can improve the convenience, speed, and economic efficiency of maintenance.

1: Zinc anode unit 2: Bolt unit
11: Insertion installation pipe 12: Blocking guide plate
13: Removal guide plate 21: Watertight insertion hole
22: watertight flange 100: driving unit
200: Chamber unit 300: Impeller unit
400: Suction pipe 500: Discharge pipe
401: fastening hole 402: fixed flange
403: Guide board assembler 404: Auxiliary fastener

Claims (5)

A driving unit 100, a chamber unit 200 that performs a pumping action by pressure changes caused by the operation of the driving unit 100, an impeller unit 300 that generates and compresses the movement of water, and a suction pipe ( In the submersible pump including 400) and a discharge pipe 500 that moves the sucked water and discharges it to the outside;
The suction pipe 400 is further formed with a zinc anode unit 1 that is attached and detachable in an insertable structure on the inner diameter surface;
The zinc anode unit (1) is integrated with an insertion pipe (11) of a conical piping structure whose diameter gradually widens toward the lower surface, and is arranged at regular intervals around the inner diameter surface of the insertion pipe (11). It is formed of a plurality of blocking guide plates (12);
The zinc anode unit (1) formed of the insertion installation pipe (11) and the blocking guide plate (12) is formed of a zinc steel sheet material,
The suction pipe 400 has a plurality of fastening holes 401 arranged around the lower outer diameter surface;
The zinc anode unit (1) forms a fastening flange (111) provided with a plurality of fastening assembly holes (P) around the outer diameter surface of the lower end of the insertion installation pipe (11);
Corrosion resistance and maintainability are characterized by providing fixing force to the joint area between the suction pipe 400 and the zinc anode unit 1 by fastening the bolt B through the fastening hole 401 and the fastening assembly hole P. An improved zinc anode unit for submersible pumps.
delete A driving unit 100, a chamber unit 200 that performs a pumping action by pressure changes caused by the operation of the driving unit 100, an impeller unit 300 that generates and compresses the movement of water, and a suction pipe ( In the submersible pump including 400) and a discharge pipe 500 that moves the sucked water and discharges it to the outside;
The suction pipe 400 is further formed with a zinc anode unit 1 that is attached and detachable in an insertable structure on the inner diameter surface;
The zinc anode unit (1) is integrated with an insertion pipe (11) of a conical piping structure whose diameter gradually widens toward the lower surface, and is arranged at regular intervals around the inner diameter surface of the insertion pipe (11). It is formed of a plurality of blocking guide plates (12);
The zinc anode unit (1) formed of the insertion installation pipe (11) and the blocking guide plate (12) is formed of a zinc steel sheet material,
The suction pipe 400 forms a fixed flange 402 provided with a sliding fastening groove (H) around the lower outer diameter surface;
The zinc anode unit (1) forms a detachable flange (112) provided with a sliding fastener (D) around the outer diameter surface of the lower end of the insertion tube (11);
Corrosion resistance and maintainability, characterized by providing fixing force to the joint area between the suction pipe 400 and the zinc anode unit 1 by the sliding insertion locking structure by the sliding fastening groove (H) and the sliding fastener (D) An improved zinc anode unit for submersible pumps.
A driving unit 100, a chamber unit 200 that performs a pumping action by pressure changes caused by the operation of the driving unit 100, an impeller unit 300 that generates and compresses the movement of water, and a suction pipe ( In the submersible pump including 400) and a discharge pipe 500 that moves the sucked water and discharges it to the outside;
The suction pipe 400 is further formed with a zinc anode unit 1 that is attached and detachable in an insertable structure on the inner diameter surface;
The zinc anode unit (1) is integrated with an insertion pipe (11) of a conical piping structure whose diameter gradually widens toward the lower surface, and is arranged at regular intervals around the inner diameter surface of the insertion pipe (11). It is formed of a plurality of blocking guide plates (12);
The zinc anode unit (1) formed of the insertion installation pipe (11) and the blocking guide plate (12) is formed of a zinc steel sheet material,
The suction pipe 400 forms a plurality of horizontally penetrating guide plate assembly holes 403 arranged at regular intervals around the central portion of the outer diameter;
The zinc anode unit (1) is formed with a detachment guide plate (13) in the form of an independent divided part with an assembly nut member (131) protruding from one outer surface in an integrated configuration;
The detachable guide plate 13 is assembled and installed around the inner diameter surface of the suction pipe 400 in a regular spaced arrangement by fastening the bolt unit 2 through the guide plate assembly hole 403 and the assembly nut member 131,
The guide plate assembly hole 403 of the suction pipe 400 forms an auxiliary fastening hole around the outer surface;
The bolt unit (2) for fastening and fixing the detachment guide plate (13) to the inner diameter surface of the suction pipe (400) includes a watertight insertion port (21) of a protruding extension structure to which the main fastening bolt (211) is coupled to the central portion, and the watertight insertion port (21). ) A zinc anode unit for a submersible pump with improved corrosion resistance and maintainability, characterized in that it is formed of a configuration including a watertight flange (22) to which an auxiliary fastening bolt (221) is coupled around the outer surface. delete