KR20130057017A - Pump with multiple stage of impeller - Google Patents

Abstract

PURPOSE: A multi-stage water pump is provided to obtain high output without increasing the number of laminated impellers and to reduce power consumption, thereby obtain high output efficiency and energy efficiency. CONSTITUTION: A multi-stage water pump comprises a case(130), a driving shaft(111), and impellers(120). An installation space is formed inside the case, and the case includes a fluid inlet(131) and a fluid outlet(150). The driving shaft is connected to a driving motor(110) and arranged inside the installation space. The impellers are installed separately along a longitudinal direction of the driving shaft. Diameters of the impellers are increased from the impellers adjacent to the fluid inlet to the impellers adjacent to the fluid outlet.

Description

Multi-Stage Submersible Pump {PUMP WITH MULTIPLE STAGE OF IMPELLER}

The present invention relates to a multistage submersible pump in which a plurality of impellers are arranged in a stacked form, and more particularly, to a multistage submersible pump capable of increasing the total output with a small driving force by changing the diameter of each impeller.

In general, the submersible pump has a structure in which the drive shaft and the impeller coupled thereto are rotated by the driving of the driving motor, and the fluid of the lower part is discharged to the upper part by using the centrifugal force generated in the rotation process.

Due to the rotation of the impeller, a pressure difference is generated between the center of the impeller and its surroundings. In other words, when a vacuum is instantaneously formed in the center of the impeller during rotation, the fluid around it is sucked into the center and flows into the diffuser of the impeller.

Using this principle, a multi-stage submersible pump is proposed to increase the total discharge pressure and the discharge head by arranging a plurality of impellers in a vertically stacked form so that the above process is repeatedly repeated for each impeller.

However, the conventional multi-stage submersible pumps all have the same diameter of each impeller, so in order to increase the output of the entire pump, it was inevitably produced only by increasing the number of stacked impellers.

As a result, the size of the pump is unnecessarily large and, as a result, the overall power consumption is increased, resulting in a decrease in energy efficiency.

Korea Utility Model Publication 1997-49855

The present invention has been proposed in order to solve such conventional problems,

Without increasing the number of stacking impeller, it is possible to obtain a higher output than conventional, and to reduce the required driving power, and to provide a multi-stage submersible pump that can simultaneously obtain high output efficiency and energy efficiency.

An embodiment of the present invention having this purpose is

A case having an installation space formed therein and having a fluid inflow portion and a fluid discharge portion, a drive motor connected to the case, a drive shaft connected to the drive motor and positioned in the installation space, and spaced along a longitudinal direction of the drive shaft; Including a plurality of impellers placed and installed,

The diameter of the impellers arranged toward the discharge portion from the impeller close to the inflow portion of each impeller is characterized in that gradually increasing.

The casing is divided into a diameter change section in which the diameter of the impeller gradually increases, and a diameter maintenance section in which the diameter is uniformly formed, and the diameter of each impeller located in the diameter change section of each impeller is discharged from the inlet side. Can be increased toward the side.

In addition, the number of impellers in the diameter change section and the diameter maintenance section may be the same.

And an impeller lower cover positioned between the inlet part and the impeller closest to the inlet part and having a diameter larger than the impeller diameter.

The present invention having these various embodiments,

Even if the number of impellers is not increased, a high output efficiency can be obtained with less driving power than the conventional one.

In addition, under the same pump discharge head and operating time as before, the power consumption is naturally reduced as compared with the conventional art.

1 is a full cross-sectional view
Figure 2 is an enlarged view of the portion A of Figure 1

Hereinafter, specific configurations and effects of the present invention will be described based on the illustrated configuration examples.

FIG. 2 is an overall sectional view of the present invention, and FIG. 3 is an enlarged view of the diameter change state of the impeller.

The multistage submersible pump of the present invention includes a driving motor 110, an impeller 120, and a casing 130 as shown in FIG. 2.

The driving motor 110 serves as a driving source for imparting the rotational force of the impeller 120 to be described later in the pumping process of the fluid, using a general DC or AC motor, the one end of the long drive shaft 111 is connected to drive It has a structure that is rotated by a motor.

The impeller 120 has a function of forming the discharge pressure of the fluid required for actual pumping, and a center thereof is penetrated by the drive shaft 111 to be rotated integrally with the drive shaft 111.

At this time, the impeller 120 is disposed in plural intervals along the longitudinal direction of the drive shaft 111 like a general multi-stage crystal pump.

As the plurality of impellers 120 are arranged in this way, the difference between the discharge pressure of the initial stage impeller discharge port 121 and the discharge pressure of the last stage impeller discharge port 122 is increased, and thus, the pump 100 by the discharge pressure difference. It is possible to increase the total discharge amount and discharge head.

The impeller 120 includes a diffuser formed between the plurality of impeller blades and the impeller blades to become a moving path of the fluid, and a shaft insertion hole is formed at the center to be inserted into the drive shaft 111 of the drive motor 110.

The casing 130 is formed to surround the impeller 120, and the inner wall is formed to be spaced apart from the end of the impeller 120 by a predetermined distance so that the rotation of the impeller 120 does not interfere with the rotation of the impeller 120. The inlet 131 is formed and the upper end is formed to have a discharge unit 150 for discharging the fluid.

The casing 130 is formed with a plurality of inflow holes 141 so that external fluid flows in.

According to the present invention, the impeller 120 is connected to the drive shaft 111 of the driving motor 110 in multiple stages, the diameter of which gradually increases from a recently joined impeller to a predetermined unit impeller at the inlet 131 of the casing 130. Consists of the configuration.

Inside the casing 130 is formed a diameter maintenance section (B) is formed the same diameter and diameter change section (A) of the diameter of the impeller 120, the diameter change section (A) is the drive motor 110 and It is formed in the lower portion of the adjacent casing 130, the diameter maintenance section (B) is formed from the upper end of the diameter change section (A) to the discharge section.

The number of impellers 120 having angles disposed in the diameter change section A and the diameter maintenance section B may be the same, and the number of impellers arranged in the diameter change section A and the diameter maintenance section B may be equal to each other. It may be different.

If the number is different, the number ratio of the impeller located in the diameter change section (A) and the diameter maintenance section (B) may be about 40%: 60 :.

Of course, such a number difference may vary in accordance with the size of the outer diameter of the impeller, and may also change from time to time depending on the amount of power and the amount of fluid used.

That is, the number of the impeller 120 and the casing 130 may be increased or decreased according to the pump head and the volume.

Here, in order to adjust the total fluid discharge amount and the discharge head value, it is necessary to adjust the diameter increase rate between the impellers 120 disposed in the diameter change section (A), the diameter increase rate is a predetermined reference value (for example, 3 ~ If less than 5%), the effect of reducing the power consumption of the drive motor 110 due to the reduction of the coefficient of friction acting on the impeller 120 according to the diameter is reduced.

In addition, when the diameter increase rate is greater than a predetermined reference value, the phenomenon that the fluid flow between the adjacent impeller 120 may not be smooth due to the diameter difference between the adjacent impeller 120.

Therefore, the diameter increase ratio of the impeller can be properly adjusted to obtain a desired fluid discharge amount and discharge head.

The number of impellers 120 disposed in the diameter change section A and the diameter maintenance section B may be variously applied according to the discharge amount and the discharge head of the pump.

In addition to this configuration, a separate impeller lower cover 123 is installed between the inlet part and the impeller closest to the inlet part, and the impeller lower cover 123 forms a transfer section of the fluid by inducing gravity reduction during the rotation of the impeller. It is to play a role.

At this time, the outer diameter of the impeller lower cover 123 is formed larger than the diameter of the lowermost impeller, because the buoyancy is generated on the lower surface of the impeller lower cover 123 when the pressure generated when each impeller is rotated from below Then, the phenomenon of holding each impeller by buoyancy occurs, which in turn has the effect of reducing the gravity applied to the entire impeller.

As gravity decreases like this, it has the effect of sending the fluid transported from below farther.

Hereinafter, the operation of the present invention by such a configuration.

First, when the driving motor 110 is driven to suck water or fluid and discharge the water through the discharge part, each impeller 120 is simultaneously rotated by the rotation of the drive shaft.

At this time, the fluid is introduced into the casing through the inlet 131 of the casing 130 due to the pressure difference generated by the rotation of the impeller 120 as shown in FIG.

When the fluid movement process due to the pressure difference is described in more detail, as the impeller 120 rotates, the fluid is pushed from the front end to the rear end of the impeller, and the fluid is sucked to fill the space with the surrounding fluid. .

The fluid introduced into the inlet 131 of the casing 130 gradually increases in pressure as it passes through the plurality of impellers 120 while moving inside the casing 130, resulting in the discharge portion of the pump 100 ( The discharge pressure at 150 is increased in proportion to the number of arrays in the stage of the impeller 120.

In more detail, as shown in [Fig. 3], the impeller 120 in the diameter change section A starts in a state in which the diameter is smaller than in the prior art, and the diameter changes gradually toward the upper impeller, so that the impeller 120 and the casing inner wall change. The separation distance is increased, and with this, the discharge amount and discharge head of the fluid that the impeller can deliver are increased.

In addition, as the diameter of the lowermost impeller is smaller than that of the related art, the contact area of the impeller 120 in contact with the fluid decreases, and the separation distance between the impeller 120 and the inner wall of the casing increases, which is related to the fluid and the impeller. Since the coefficient of friction is also reduced, the power required for driving the impeller is reduced.

Therefore, the efficiency increases as the rotation of the rotating shaft increases.

That is, a large amount of fluid causes a large buoyancy according to the rotational speed of water, thereby reducing wear of thrust bearings.

As a result, when the same driving power is supplied as compared with the related art, in the pump according to the present invention, the discharge amount and the discharge head may be increased.

The fluid passing through the diameter change section (A) is additionally increased in pressure while passing through the diameter maintenance section (B), and is discharged through the discharge part 150 and finally discharged through the drain pipe 200.

Features of the present invention described above may be implemented by various modifications and combinations by those skilled in the art, but these modifications and combinations are related to the configuration and the purpose of increasing the overall discharge efficiency by varying the diameter of each of the plurality of impellers arranged If any, it should be determined that it belongs to the protection scope of the present invention.

110: drive motor 111: drive shaft
120: impeller 130: casing
150: discharge portion A: diameter change section
B: Diameter maintenance section

Claims (4)

A case having an installation space therein and having a fluid inlet and a fluid outlet,
A drive motor connected to the case and a drive shaft connected to the drive motor and positioned in the installation space;
It includes a plurality of impellers spaced along the longitudinal direction of the drive shaft,
The diameters of the impellers arranged toward the discharge portion from the impeller close to the inflow portion of each impeller are gradually increased
Multi-stage submersible pump.
In claim 1,
The casing is divided into a diameter change section in which the diameter of the impeller gradually increases, and a diameter maintenance section in which the diameter is constantly formed.
The diameter of each impeller located in the diameter change section of each impeller is increased from the inlet side to the discharge side
Multi-stage submersible pump.
3. The method of claim 2,
The number of impellers located in the diameter change section and the diameter maintenance section is the same.
Multi-stage submersible pump.
4. The method according to any one of claims 1 to 3,
Located between the inlet inlet and the impeller closest to the inlet,
Impeller lower cover having a diameter larger than the impeller diameter
Multistage submersible pump further comprising a.

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