KR100650032B1 - Vacuum Suction Underwater Pump - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum suction submersible pump for suctioning and discharging fluid. The fluid is sucked by the rotation of the impeller by the driving motor and passes through the nozzle of the discharge pipe. It aims to discharge a large amount of fluid by induction and small power.

The vacuum suction submersible pump according to the present invention includes a drive motor for forming a magnet in a coil by supplying power, a drive shaft rotatably installed at a central portion of the drive motor, and an impeller integrally coupled to one end of the drive shaft. And a vacuum suction submersible pump having a suction port for discharging and discharging the fluid by the rotation of the impeller, the vacuum suction submersible pump comprising: a discharge port for discharging the fluid sucked by the rotation of the impeller; A nozzle connected to the outlet and the fastening member; A discharge pipe inserted into the nozzle and coupled to the fastening member; It is coupled to one side of the discharge pipe is inclined at a predetermined angle, and again in parallel with the suction port of the main body side by side extending in the longitudinal direction is provided with a conical hook net in the end portion; characterized in that it comprises a.

Suction pipe, discharge pipe, nozzle, drive motor, submersible pump.

Description

Vacuum Suction Underwater Pump

1 is a front view of a conventional submersible pump.

2 is a cross-sectional view of FIG. 1.

3 is a cross-sectional view of the submersible pump according to the present invention.

4 is a partially enlarged cross-sectional view of FIG. 3.

<Explanation of symbols for main parts of drawing>

10 .... Main Unit 20 .... Outlet

21 .... Outlet 30 .... Nozzle

40 .... Impeller Case 41 .... Impeller

50 .... discharge pipe 60 .... suction pipe

The present invention relates to a vacuum suction submersible pump for sucking and discharging a fluid, and more particularly, a fluid sucked by the rotation of an impeller by a driving motor passes through a nozzle of the discharge pipe and is sucked at a relative pressure difference from the suction pipe. The present invention relates to a vacuum suction submersible pump capable of inducing a fluid flow into a pipe to discharge a large amount of fluid with a small power.

In general, an underwater pump is a pump operated while the entire pump is immersed in the fluid, and rotates the drive shaft and the impeller of the driving motor by an external power source, and discharges the fluid to the upper part by the centrifugal force generated thereby. . By rotating the impeller, a vacuum is generated at the center of the fluid by centrifugal force, and the fluid is sucked into the vacuum.

Such a conventional submersible pump 100, as shown in Figure 1 and 2, the cable box (Cable Box, 110) in which the cable (Cable, 111) is supplied from the outside power; A moving ring 120 for moving to a moving means such as a crane (not shown); A stator 133 for forming magnetism by the power supplied through the cable 111, a rotor 132 rotating by a magnetic field formed in the stator 133, and the rotor 132. A drive motor 130 comprising a drive shaft 131 constituting a central axis of the drive shaft 131 rotatably supported by a bearing 134a mounted at a lower end thereof; An impeller coupled to the lower end of the driving shaft 131 and rotating; An impeller case 400 surrounding an outer portion of the impeller 410; A suction port 300 which sucks and discharges the fluid by the rotation of the impeller 410; It consists of a discharge port 200 forming the discharge pipe (210).

In the submersible pump 100, the stator 133 is magnetized by externally supplied power, and the impeller 410 is rotated while the driving shaft 131 rotates by the rotation of the rotor 132. will be.

When the impeller 410 is rotated, the surrounding fluid becomes a vacuum while vortexing due to the centrifugal force. Accordingly, the fluid is introduced into the vacuum and the fluid introduced into the impeller case 400 is discharged to the outside through the discharge pipe 210.

However, according to the conventional submersible pump, the amount of fluid introduced into the inlet pipe is relatively small due to the rotation of the impeller, and the pumping amount per unit time is reduced, thereby reducing work efficiency.

In addition, when a large amount of power is supplied to increase the pumping amount per unit time, there is a problem that a large load is applied to the bearing portion that rotates the drive shaft and is easily damaged to frequently replace the bearing.

The present invention has been made to solve the above-mentioned conventional problems, by combining the nozzle between the discharge port and the discharge pipe, the suction of the fluid to the suction pipe coupled to the discharge pipe by the change of flow rate due to the relative pressure difference. It is an object of the present invention to provide a vacuum suction submersible pump capable of inducing and increasing the discharge amount with little power to improve the work efficiency.

In order to achieve the above object, the vacuum suction submersible pump according to the present invention, a drive motor for forming a magnet in the coil by the supply of power, a drive shaft rotatably installed in the center of the drive motor, A vacuum suction submersible pump having an impeller integrally coupled to one end, a suction port for discharging and discharging fluid by rotation of the impeller, and a vacuum suction submersible pump having a discharge pipe, the upper end of the main body discharging the fluid sucked by the rotation of the impeller An outlet; A nozzle coupled to the outlet and the fastening member; A discharge pipe having one end of the nozzle inserted therein and coupled to the fastening member; It is coupled to one side of the discharge pipe is inclined at a predetermined angle, in parallel with the suction port of the main body in parallel to extend in the longitudinal direction along the end of the suction pipe is provided with a cone-shaped catching net at the end; .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a sectional view of a vacuum suction submersible pump, and FIG. 4 is a partially enlarged sectional view of the present invention.

As shown in FIG. 3, the main body 10 of the vacuum suction submersible pump 80 includes a cable box 11 in which a cable 12, which is powered from the outside, is embedded, and a crane (not shown). Rotated by a moving ring 14 for moving to a moving means such as a), a stator 33 for forming a magnetic field with power supplied through the cable 12, and a magnetic field formed in the stator 33. A drive motor 13 consisting of a rotor 32 and a drive shaft 31 constituting a central axis of the rotor 32 and rotatably supported by bearings 34a and 34b mounted to the stop and lower ends. Consists of

An impeller (41) mounted at a lower end of the main body (10), in which a bearing (34b) is mounted at one lower end to transmit a rotational force of the driving shaft (31); An impeller case 40 having a shape surrounding an outer edge of the impeller 41 to protect the impeller 41; Is provided with a suction port 300 for sucking the fluid by the rotation of the impeller (41).

In the upper end of the main body 10, the fluid flowing in the suction port 300 is connected to the opening of one side of the impeller case 40 is flowed through one side of the main body 10 while the discharge passage 20 to prevent overheating Wow; A discharge port 21 through which the fluid flows out through the discharge passage 20; A nozzle (70) coupled to the outlet (21) for adjusting the flow rate of the fluid flowing at a relative pressure difference; A discharge pipe 50 into which one end of the nozzle 70 is inserted and the fluid discharged from the end of the nozzle 70 flows; It is coupled inclined at a predetermined angle to one side of the discharge pipe 50, it is coupled to form a predetermined angle to form an equilibrium with the suction port 300 of the main body 10 is extended in the longitudinal direction to the end of the cone-shaped hook net Suction pipe 60 provided with 61; is formed.

Hereinafter, the operation of the vacuum suction submersible pump according to the present invention will be described.

Power supplied from the outside through the cable 12 magnetizes the stator 33 of the drive motor 13 to form a magnetic field, and rotates the drive shaft 31 while the rotor 32 is rotated by the magnetic field thus formed. Let's do it.

The drive shaft 31 forms a central axis of the stator 33 to efficiently transmit the rotational force of the drive shaft 31 to the impeller 41, and bearings 34a and 34b are provided at the stop and the lower end of the main body 10. It is installed.

When the impeller 41 is rotated by the rotation of the drive shaft 31, the inside thereof becomes a vacuum state due to the centrifugal rotational power, and fluid flows into the impeller case 40 from the suction port 300 at the lower end of the main body 10. It is sucked and the fluid is discharged to the discharge passage 20 which is connected to the opening of one side inside the impeller case (40).

The impeller case 40, it is preferable to suppress the internal temperature rise due to the rotation of the impeller 41 and to have a shape protruded outward to secure the flow space.

The discharge passage 20 serves to act as a passage through which the fluid flowing in the impeller case 40 moves to the discharge port 21 and to prevent overheating of the drive motor 13 due to the rotation of the drive shaft 31. The fluid that is formed long on one side of the driving motor 13 and moves the discharge passage 20 is discharged to the outside through the discharge port 21.

Figure 4 shows a partially enlarged cross-sectional view of the site where the fluid is discharged. As shown in Figure 4, the discharge portion of the vacuum suction submersible pump is coupled to the outlet 21, the diameter (D) is reduced from one end to the end in order to adjust the flow rate of the fluid flowing with a relative pressure difference ( D → D '), the nozzle (70) having a pipe shape extending a certain length from the end to the same diameter (D'), and one end of the nozzle 70 is inserted, the nozzle 70 The discharge pipe 50 extended by a predetermined length so as to move the fluid discharged from the end of the inclined to be inclined at a predetermined angle to one side of the discharge pipe 50, and to be in equilibrium with the main body 10 again It is coupled to form a predetermined angle, and extends to the lower end of the main body 10 is composed of a suction pipe 60 having a conical hook net 61 in the end portion.

Since the nozzle 70 has a diameter D of the inlet part larger than the end diameter D ', the flow pressure P of the fluid passing through the outlet 21 is equal to that of the fluid passing through the nozzle 70 end. It becomes larger than the flow pressure P '. Therefore, the moving speed V 'of the fluid passing through the end of the nozzle 70 becomes faster.

That is, since the diameter D of the outlet 21 is drastically reduced to D 'by the nozzle 70, part of the pressure energy of the fluid is converted into velocity energy, so that the pressure at the nozzle outlet is reduced and the speed is increased. Therefore, the fluid passing through the outlet 21 passes through the end of the nozzle 70 and the speed thereof is further increased and the pressure is reduced, so that the fluid flowing into the suction pipe 60 is discharged while sucking. Thereby, the amount of water injected through the discharge pipe 50 is to be increased than the amount of water passing through the discharge port 21.

The suction pipe 60 is coupled to one side of the discharge pipe 50 inclined at a predetermined angle, and is coupled to form a predetermined angle so as to be in equilibrium with the main body 10 again, the predetermined lower end of the main body 10 Extends as long as its length.

The fluid introduced through the conical hook net 61 provided at the end of the suction pipe 60 moves upward along the suction pipe 60 and is connected to the suction pipe 60 and the discharge pipe 50. The mixed with the fluid ejected to the discharge pipe 50 through the nozzle 70 is discharged to the outside.

In other words, the water flowing into the suction port 300 of the lower end of the main body 10 is discharged to the upper by the impeller 41, the suction pipe 60 to the particles by the catching net 61 provided at the end thereof Sludge, sand, dirt, etc., in which coarse impurities are filtered out are sucked together with water and discharged to the upper portion.

Although specific embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and the general knowledge in the field to which the present invention pertains is not limited to the scope of the invention described in the claims. Anyone with a variety of changes will be possible.

As described above, the vacuum suction submersible pump according to the present invention increases the pumping amount per unit time by installing a nozzle in an existing fluid discharge passage and connecting a separate suction pipe. In addition, since the suction pipe is installed at the lower end than the suction port of the main body, water is sucked out by the impeller, and the suction pipe can suck out the water, sludge, sand and dirt, etc., thereby improving work efficiency.

Claims (1)

A drive motor for forming magnetism in the coil by supply of power, a drive shaft rotatably installed at the center of the drive motor, an impeller integrally coupled to one end of the drive shaft, and suction of fluid by rotation of the impeller In the vacuum suction submersible pump consisting of the suction port and the discharge port and discharge pipe, It is provided in one direction of the main body 10 in the vertical direction, the lower portion is in communication with the inlet port 300 and the discharge port 21 is formed in the upper portion, the discharge passage for discharging the fluid sucked by the rotation of the impeller 41 to the upper portion ( 20); Consists of a parallel portion and a cross-sectional reduction portion, a fastening hole is formed in one flange portion of the parallel portion is coupled to the outlet 21 and the fastening member, and a fastening hole is formed in the flange portion of the parallel end portion is fastened with the discharge pipe 50 A nozzle 70 coupled to the member; In the state where the cross-sectional reduction portion of the nozzle 70 is inserted into the inside, the nozzle 70 is coupled to the flange portion and the fastening member at the end of the parallel portion, and has a structure in which the diameter after being joined with the suction pipe 60 is expanded. Pipe 50; Branched inclined at a predetermined angle in the downward direction from one side of the discharge pipe 50 is bent to parallel to the discharge passage 20 of the main body 10, below the position of the suction port 300 of the main body 10 A suction pipe 60 having a cone-shaped catching net 61 at an end extending in a long direction; Vacuum suction submersible pump comprising a.

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