KR101634968B1 - A pumping type underwater pump - Google Patents

Abstract

[0001] The present invention relates to a pumping operation type submersible pump, and more particularly, to a pumping operation type submersible pump which is capable of performing a volumetric pumping operation by a virtual piston formed by a reciprocating motion of a pumping rotating body, will be.
That is, the present invention provides a submersible pump, wherein the pump rotating body is constituted by one of an impeller and a screw, the pump housing, the driving part and the pumping rotating body are vertically arranged, the pumping rotating body is provided at the lowermost part, And pumping driving means for reciprocating the rotating body to form a virtual piston which performs a volumetric pumping operation.
Accordingly, the present invention provides pumping driving means for causing a pumping rotator formed of an impeller or a screw to reciprocate to form a virtual piston for performing a volumetric pumping operation, so that the pumping rotator is rotated by the rotation of the pumping rotator, And the suction force and the discharge pressure are increased.
Also, since the suction force is increased, the self-absorption of the particle material such as manure such as manure, high-viscosity sludge such as mortar and pulp mixture is easy, and the volumetric pumping action is performed along with the transportation by rotation It is clearly conveyed without damaging the conveying object having the same length as the conveying object or algae mixed with the foreign substance.

Description

[0001] The present invention relates to a pumping type underwater pump,

The present invention relates to a pumping operation type submersible pump, and more particularly, to a submersible pump which has a pump housing, a driving unit and a pumping rotation unit vertically arranged, a pumping rotation unit disposed at the bottom, And a volume pumping operation by a virtual piston formed by the reciprocating motion of the pumping rotating body.

In general, a pump is one that imparts transferring energy to the fluid in a transportable manner.

Such pumps include a piston pump, an axial flow pump, a centrifugal flow pump, a gear pump, a vane puff, and a rotary pump.

The axial flow pump includes an impeller pump having a plurality of blades at equal intervals around a pump axis, and a screw pump provided on the outer surface of the pump shaft so as to have spiral wings continuously.

The impeller pump includes a cylindrical pump housing and a pumping rotor housed in the pump housing. The impeller rotates the pumping object within the pump housing by lifting force generated by wings provided on the pump shaft.

The screw pump is accommodated in a cylindrical pump housing and the pump housing, and the pump rotating body is composed of a screw, and the object to be transported is pushed by a wing formed in a spiral shape on the outer circumference of the pump shaft.

On the other hand, the submersible pump is constituted by a centrifugal type pump in which the pumping rotator induces a toe output by the centrifugal force.

However, the conventional submerged pump as described above is constructed such that the pump rotating body induces centrifugal force to transfer the conveyed object, and is made of particulate matter such as foreign matter mixed liquid such as manure, high viscosity sludge such as mortar and pulp mixture There is a problem that the conveying of the conveying object is not easy.

In addition, the conventional submersible pump has a problem in that it is not easy to transfer the object to be conveyed with the foreign substance or the object to be conveyed having the length.

Korean Patent Publication No. 1994-0021940

Accordingly, it is an object of the present invention to solve the above-mentioned problems in that the conventional submersible pump is not easy to transfer a conveyance object made of a particulate material such as manure, a high viscosity sludge such as muller and pulp mixture, So that it is not easy to transfer the object to be conveyed or the object to be conveyed having a length.

That is, the present invention provides a submersible pump, wherein the pump rotating body is constituted by one of an impeller and a screw, the pump housing, the driving part and the pumping rotating body are vertically arranged, the pumping rotating body is provided at the lowermost part, And pumping driving means for reciprocating the rotating body to form a virtual piston which performs a volumetric pumping operation.

Accordingly, the present invention provides pumping driving means for causing a pumping rotator formed of an impeller or a screw to reciprocate to form a virtual piston for performing a volumetric pumping operation, so that the pumping rotator is rotated by the rotation of the pumping rotator, And the suction force and the discharge pressure are increased.

Also, since the suction force is increased, the self-absorption of the particle material such as manure such as manure, high-viscosity sludge such as mortar and pulp mixture is easy, and the volumetric pumping action is performed along with the transportation by rotation It is clearly conveyed without damaging the conveying object having the same length as the conveying object or algae mixed with the foreign substance.

FIG. 1A is a perspective view of a main constitution showing that a pumping rotating body is constituted by an impeller in an embodiment according to the present invention. FIG.
FIG. 1B is a perspective view of a main constitution showing that a pumping rotating body is constituted by a screw in one embodiment according to the present invention. FIG.
Fig. 2 is an assembled cross-sectional view according to Fig. 1b. Fig.
FIG. 3 is a perspective view of a main constitution in which the pumping rotator is formed as a bifurcated lobe in the embodiment according to FIG. 1b.
Fig. 4 is an exemplary view showing that a telescopic shaft according to the present invention is implemented with a ball spline shaft as a female part; Fig.
FIG. 5 is an exemplary view showing a telescopic shaft according to an embodiment of the present invention when the spline shaft is used as a female part; FIG.
FIG. 6 is an exemplary view showing that a telescopic shaft according to the present invention is implemented with a serration axis as a female part;
FIG. 7 is an exemplary view showing that a telescopic shaft according to the present invention is implemented with a groin shaft as a shaft; FIG.
FIG. 8 is an exemplary view showing that a telescopic shaft according to the present invention is implemented with a female portion of a bellows shaft; FIG.
9A and 9B are views showing an example in which the pumping driver according to the present invention is constituted by a cam actuator composed of a reciprocating drive column.
10 is an exemplary view showing that the pumping driver according to the present invention is constituted by a cam actuator having cam protrusions and cam grooves.
11 is a view showing an example in which the pumping driver according to the present invention is constituted by a solenoid actuator.
FIG. 12 is an exemplary view showing a pumping actuator according to the present invention constructed as a pneumatic actuator. FIG.
13 is a view showing an example in which the pumping driver according to the present invention is formed of a reciprocating drive pinion gear.

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

The present invention relates to a method and apparatus for conveying a conveyed object by a pumping rotator by rotation and volumetric pumping by a virtual piston, thereby improving the self-excitation force and the ejection pressure to provide a liquid mixture of foreign matter such as manure, So that the particle type conveying object such as high viscosity sludge can be easily and clearly conveyed.

1 and 2, the present invention includes a pumping rotating body 200 having a spiral 210 on an outer circumference of a pump shaft 220, A pump housing 100 formed in a cylindrical shape and having a discharge port 112 formed on one side thereof and a discharge port 112 formed on the other side thereof and a pump housing 100 provided on one side of the pump housing 100, Wherein the pump rotating body is configured to be one of an impeller and a screw and the pump housing and the pumping rotating body 200 And the driving unit 300 are arranged vertically and the pumping rotating body 200 is provided at the lowermost side of the pump housing 100 and the pumping rotating body 200 is reciprocated to perform a volumetric pumping operation And pumping drive means for causing the piston to be formed.

Here, the pump housing 100 is formed in a cylindrical shape, and a pumping stroke space of the pump rotating body 200 is formed therein. The pump housing 100 is provided with an inlet (not shown) And a discharge port 112 is formed on a side surface of the pump housing 100 on the driving unit 300 of the pump rotating body 200. [

When the conveying guide curved body 120 for guiding the conveyed object to the discharge port 112 is provided at the edge formed on the inner wall of the pump housing 100 on the discharge port 112 side of the pump housing 100, It is possible to prevent defective conveyance of the vortex in the vortex.

Meanwhile, as shown in FIG. 3, the vanes of the pumping rotation body 200 can be multi-bladed.

The driving unit 300 may selectively implement any one of an electric motor, a hydraulic motor, and an engine.

In addition, the pumping driving means includes a driving shaft 300 and a pivoting shaft for axially coupling the pumping rotating body 200 so as to absorb a change in axial length, and a pumping operation And a pumping driving unit.

Hereinafter, a description will be made of an embodiment of the extensible shaft joint portion as follows.

As shown in FIG. 4, the extensible shafts and concave portions are provided on either one of the driving unit 300 and the pumping rotating body 200, and the spline groove, the driving unit 300 and the pumping rotating body 200 And a spline shaft which is formed on the other side of the spline groove and is axially coupled to the spline tube and a spline shaft which is accommodated in the spline groove and provided in the spline groove, And a sound part 400 as shown in FIG.

As shown in FIG. 5, the extensible shafts are disposed on either one of the driving unit 300 and the pumping rotating body 200, and the spline pipe, the driving unit 300, and the pumping rotating body 200, And a spline shaft which is provided on the other side of the spline shaft and which is formed on the outer surface of the spline tube and is axially coupled with the spline tube.

As shown in FIG. 6, the extension / contraction shaft coupling part is provided on either one of the driving part 300 and the pumping rotating part 200, and a serration tube, a driving part 300 and a pumping rotating body The serration axis of the serration shaft may be formed on the other side of the serration axis, and the serration axis may be formed on the outer surface of the serration shaft to be axially coupled with the serration tube.

As shown in FIG. 7, the extensible shafts and concave portions are formed on one side of the driving unit 300 and the pumping rotating body 200, and are formed of polygonal tubular bodies. The driving unit 300 and the pumping rotating body 200 And a polygonal prism 430 formed of a polygonal rod corresponding to the polygonal tube and formed of a polygonal bar that is axially coupled to the polygonal tube.

8, the bellows shaft 440 is constituted by a bellows tube body in which a driving shaft of the driving unit 300 and a pump shaft of the pumping rotating body 200 are axially coupled and elongated and contracted in the longitudinal direction, As shown in FIG.

In addition, the extensible shafts and concave portions can be implemented by applying all the extensible shafts applied to the shaft coupling in addition to the above-described embodiments.

Hereinafter, an embodiment of the pumping driver will be described.

The pumping driving unit includes a cam actuator for pumping the pump shaft 220 of the pumping rotating body 200 in the axial direction.

9A, the cam actuator includes a reciprocating driving column 511 inclined to the pump shaft 220 and a reciprocating driving column 511 connecting the reciprocating driving column 511 to the shaft housing 310, And a pull bar 512.

The reciprocating driving draw bar 512 is coupled to the shaft housing 310 in a rotatable manner and extensively connected to the end of the draw link 512a and a draw link 512a coupled to the shaft housing 310 in the axial direction, And a column restraining bearing portion 512b for restraining rotation of the outer periphery of the column restraining bearing portion 512b.

9B, the cam actuator has a decelerating shaft 514 that is electrically coupled to the driving unit 300 and the decelerating gear 513. The reciprocating driving column 511, which is inclined to the decelerating shaft 514, And a reciprocating drive draw bar 512 which rotatably restrains the pump shaft 220 by rolling the reciprocating drive column 511.

10, the cam actuator includes a cam protrusion 521 on one side of the pump shaft 220 and the inner wall of the shaft housing 310, and on the other side of the cam protrusion 521, And a cam groove 522 for reciprocating the pump shaft 220 according to the rotation of the pump shaft 220.

As shown in FIG. 11, the pumping driving unit may include a solenoid actuator (not shown) for pumping the pumping rotating body 200 by a magnetic force in the axial direction and returning the pumping rotating body 200 by the rotational discharging pressure 530).

As shown in FIG. 12, the pumping actuator may include a pneumatic actuator 540 for pumping the pump shaft 220 in the axial direction by a pneumatic pressure.

As shown in FIG. 13, the pumping driving unit includes a gear housing 551 that is axially slidably received in the shaft housing 310 and a sliding portion 551 that is slidably mounted on the driving unit 300 side of the gear housing 551. [ A drive bevel gear 552 which is axially supported and axially connected to the drive unit 300; a pump bevel gear 553 which is axially mounted on the pump side of the gear housing 551 and is fixed to the pump shaft 220; A reciprocating driving pinion gear 554 and a reciprocating driving pinion gear 555 provided on both sides so as to be coupled with each other between the pump bevel gear 553 and the pump bevel gear 553 and the reciprocating driving pinion gear 555 provided on the reciprocating driving pinion gear 554, And a reciprocating motion guide groove 556 for guiding the axial housing to reciprocate in the axial direction by limiting the axial flow and allowing the axial flow to flow only in the width direction.

In addition to the above-described embodiments, the present invention can also be implemented by applying a pumping driving method in which the pumping rotating body 200 is operated in a volumetric pumping operation in conjunction with a rotating operation.

In the virtual piston-type pumping operation of the pumping rotating body 200 by the pumping driving unit, the return stroke speed is set to be the pressing stroke speed (speed) so as to minimize the generation of negative pressure in the discharge port 112 during the return stroke of the pumping rotating body 200, It is desirable to perform the operation at a later speed.

Hereinafter, the operation of the present invention will be described.

As described above, in the submerged pump, the pump rotating body 200 is formed of one of an impeller and a screw, the pump housing 100, the pumping rotating body 200 and the driving unit 300 are vertically arranged, And a pumping drive means for rotating the pumping rotating body to form a virtual piston for performing a volumetric pumping operation, wherein the rotating body is provided at the lowermost side of the pump housing, The driving means includes a pivoting shaft for axially coupling the driving shaft of the driving unit 300 and the pumping rotating body 200 so as to absorb a change in axial length, a pumping unit for pivoting the pumping unit 200 in the axial direction, The submersible pump to which the present invention is applied is installed in a reservoir containing a foreign matter such as manure and a particle type conveying object such as mud and high viscosity sludge such as mortar and pulp mixed liquid to operate the driving unit 300 , Are pushed to be transported by the pumping rotating body 200 by the rotation of the transfer object is the pump housing be introduced through an inlet 111 formed at the bottom to be opened in all directions of 100, driver 300.

At this time, the pumping rotating body 200 performs a volumetric pumping operation inside the pump housing 100 by the pumping driving unit of the pumping driving means.

As described above, when the volumetric pumping operation is performed by the pumping rotating body 200, the cross sectional area projected in the axial direction of the pumping rotating body 200 is formed in the pumping stroke process by the pumping driving unit, (200) forms a virtual piston, and the object to be conveyed is pumped and discharged to the discharge port (112) side which is opened to the upper part of the pumping housing (100).

Then, the pumping rotator 200 is returned to the return stroke by the pumping driving unit, and the conveying object pushed toward the discharge port 112 side through the pumping stroke process is continuously transferred to the discharge port 112 side by the inertial flow And the pumping rotating body 200 is returned to the full stroke position.

As the above process is repeatedly performed, the suction force and the discharge pressure are improved, and the transported object is transported clearly and efficiently.

The edge of the pump housing 100 and the inlet port 111 and the outlet port 112 formed on the inner wall of the pump housing 100 at the entrance side of the pump housing 100, When the conveying guide curved body 120 is provided, defective conveyance of the conveyed object to the vortex at the corners is prevented.

If the return stroke of the pumping actuation unit is lower than the pumping stroke, the transferring resistance of the object to be inertially flowed is minimized and a negative pressure is formed on the discharge port 112 side in the pumping return stroke of the pumping rotating body 200 I will not.

As shown in FIGS. 4 to 7, the expansion and contraction axis may include a ball spline shaft 400 and a spline shaft 410, a serration shaft concave 420, and a polygonal shaft 430 The coupling between the driving unit 300 and the pumping rotating body 200 is facilitated.

If the bellows shaft 440 is constructed as shown in FIG. 8, the noise is minimized during the virtual piston pumping process by the pumping driving unit.

In addition, if the pumping driver is constructed as a cam actuator as shown in FIG. 9A, the configuration is simplified and the operation is clearly made.

9B, there is provided a reciprocating driving column 511 having a decelerating shaft 514 which is electromagnetically coupled to the driving unit 300 and the decelerating gear 513, and which is inclined on the decelerating shaft 514 And a reciprocating drive draw bar 512 for rotatably restraining the pump shaft 220. The operation of the virtual piston of the pump rotating body 200 is facilitated in comparison with the rotational speed of the pump shaft 220 Can be performed by adjusting.

11 and 12, when the solenoid actuator 530 and the pneumatic-pressure actuator 540 are configured as shown in FIG. 11 and FIG. 12, the virtual piston operation of the pumping rotation body 200 is clearly performed, .

13, the gear housing 551, the drive bevel gear 552, the pump bevel gear 553, and the reciprocating drive unit 553, which are housed in the shaft housing 310 so as to be slidable in the axial direction, The virtual piston operation according to the number of revolutions of the pumping rotating body 200 can be easily controlled through the drive and the gear ratio adjustment of the pump bevel gear and the reciprocating drive pinion gear 554 .

100: pump housing
111: inlet 112: outlet
120:
200: Pumping rotor
210: wing
220: Pump shaft
300: driving part 310: shaft housing
400: Ball spline shaft
410: spline shaft joint part 420: serration axis joint part
430: polygonal axis 440: bellows axis
511: reciprocating drive column
512: reciprocating drive tow bar
512a: pull link 512b: column restraining bearing portion
513: Reduction gear 514: Reduction shaft
521: Cam protrusion 522: Cam groove
530: Solenoid actuator
540: Pneumatic and hydraulic actuators
551: Gear housing 552: Drive bevel gear
553: Pump bevel gear 554: reciprocating drive pinion gear
555: reciprocating driving traction protrusion 556: reciprocation induction groove

Claims (6)

For an underwater pump;
The pump rotating body 200 and the driving unit 300 are arranged vertically and the pump rotating body 200 is connected to the pump housing 100 100 and a pumping drive means for reciprocating the pumping rotating body 200 to form a virtual piston for performing a volumetric pumping operation,
The pump housing 100 is formed in a cylindrical shape and a pumping stroke space of the pumping rotating body 200 is formed therein. The pump housing 100 has an inlet 111, And a discharge port 112 is formed at a side of the pump housing 100 on the side of the driving unit 300 of the pump rotating body 200.
The method of claim 1, further comprising:
And a conveying guide curved body 120 for guiding the conveyed object to the discharge port 112 at an edge formed on the inner wall of the pump housing 100 on the discharge port 112 side of the pump housing 100,
The pumping driving means includes a pivoting shaft for axially coupling the driving unit 300 and the pumping rotating body 200 so as to absorb a change in axial length, a pumping unit for pumping the pumping unit 200 in the axial direction, And a driving unit for driving the pump.
3. The method of claim 2,
The extension /
A spline pipe provided on one side of the driving unit 300 and the pumping rotating body 200 and having a spline groove formed on the inner surface of the driving unit 300 and the pumping rotating body 200, A spline shaft which is formed in the spline tube and which is axially coupled with the spline tube, and a spline shaft which is accommodated in the spline groove provided in the spline tube;
A spline pipe provided on one side of the driving unit 300 and the pumping rotating body 200 and provided on the other side of the spline pipe and the driving unit 300 and the pumping rotating body 200 having splines formed on the inner surface thereof, A spline shaft formed by a spline bar axially coupled to the spline tube;
A serration tube, a driving unit 300, and a pumping rotating body 200 provided on one side of the driving unit 300 and the pumping rotating unit 200, the serration being provided on the other side of the pumping rotating body 200, And a serration shaft formed of serration rods that are axially coupled to the serration tube;
A plurality of pipes formed on one side of the driving unit 300 and the pumping rotating body 200 and formed of a polygonal tube body and a plurality of pipes provided on the other side of the driving unit 300 and the pumping rotating body 200, And a polygonal prism portion 430 formed of a polygonal rod having a polygonal cross-section and axially coupled to the polygonal tube;
A bellows shaft 440 constituted by a bellows tube body in which a driving shaft of the driving unit 300 and a pump shaft of the pumping rotating body 200 are axially coupled and elongation and contraction are generated in the longitudinal direction;
Wherein the first pump and the second pump are connected to each other.

3. The method of claim 2,
In the volumetric pumping operation of the pumping rotating body 200 by the pumping driving unit, the return stroke speed of the pumping rotation body 200 is set to be slower than the pressure stroke speed so that the negative pressure in the discharge port 112 is minimized. Wherein the pumping operation is performed by the pump.

The method according to claim 2 or 4,
The pumping driving unit includes a cam actuator for pumping the pump shaft 220 of the pumping rotating body 200 in the axial direction,
The cam actuator
A reciprocating drive column 511 inclined to the pump shaft 220 and a reciprocating drive draw bar 512 for coupling the reciprocating drive column 511 to the shaft housing 310 by rolling, The bar 512 is rotatably and retractably coupled to the end of the tow link 512a and a draw link 512a coupled to the shaft housing 310 in an axially rotationally rotated manner to rotate the outer periphery of the reciprocating drive column 511 And a column restraining bearing portion 512b for restricting the column restraint bearing portion 512b;
A reciprocating drive column 511 inclined to the decelerating shaft 514 and the reciprocating drive column 511 are connected to the decelerating shaft 514 by a rolling clutch 514, And a reciprocating driving draw bar 512 for rotatably restraining the pump shaft 220;
And a cam groove 522 formed on the inner wall of the shaft housing 310 and corresponding to the rotation of the pump shaft 220 so as to be reciprocated Wherein the pumping operation type submersible pump comprises:
The method according to claim 2 or 4,
The pumping driver
And a solenoid actuator 530 for pumping the pumping rotator 200 by magnetic force in the axial direction and causing the pumping rotator 200 to return by the rotational discharge pressure;
And a pneumatic / hydraulic actuator 540 that volumetrically pumps the pump shaft 220 in the axial direction by pneumatic pressure;
A gear housing 551 which is slidably received in the shaft housing 310 so as to be slidable in an axial direction and a drive bevel gear 552 which is slidably mounted on the drive unit 300 side of the gear housing 551 and is fixed to the drive unit 300 A pump bevel gear 553 which is axially mounted on the pump side of the gear housing 551 and is fixed to the pump shaft 220 and a pump bevel gear 553 which is installed on both sides of the drive bevel gear 552 and the pump bevel gear 553, The reciprocating driving pull projection 555 and the reciprocating driving pull projection 555 provided on the reciprocating driving pinion gear 554 and the reciprocating driving pinion gear 554 restrict the axial flow and flow only in the width direction, And a reciprocating motion inducing groove (556) for guiding the housing to reciprocate in the axial direction.

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