KR101921266B1 - A Suction cone with improved suction performance and pump with same - Google Patents

Abstract

The present invention relates to a suction cone for guiding movement of a fluid sucked into a suction port of a pump to improve suction performance, and a pump having the same. According to an embodiment of the present invention, provided is a suction cone for improving the suction performance by a vortex generating blade, which is positioned below a suction port of a pump and improves the suction performance by the vortex generating blade that guides the movement of the sucked fluid. The suction cone includes a cone body positioned at a lower portion of a suction port of a pump and having a diameter which is gradually reduced from a lower end toward an upper end to guide the movement of a fluid; a vertex generating blade for generating a vertex flow so that the fluid sucked and rotated around the center of the cone body circles and rotates corresponding to a rotation direction of an impeller; and a rotating motor installed inside the cone body to rotate the vertex generating blade. Therefore, the suction performance may be improved and the efficiency of the pump may be improved.

Description

[0001] The present invention relates to a suction cone having improved suction performance by swirling flow generating blades and a pump having the suction cone,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a suction cone for guiding movement of a fluid sucked into a suction port of a pump to improve suction performance, and a pump having the suction cone.

Generally, a pump is a device for sucking and discharging a fluid, and the pump is divided into a land pump installed on the ground and an underwater pump installed in water.

On the other hand, since the ground pump is installed on the ground, it is not influenced by the suction condition. However, in the case of an underwater pump, the impeller is rotated in a state of being locked to the fluid accommodated in the water collecting, There is a problem that the suction performance is lowered due to the turbulence generated due to the forced fluid rotation.

In order to solve this problem, a "suction guide assisting device for an underwater axial flow pump" of Korean Patent Registration No. 10-0251030 (published on May 1, 2000) has been disclosed.

A conventional guiding cone for guiding the flow of the fluid is formed of any one of a polygonal pyramid or a conical shape which is located at the inlet side of the underwater axial flow pump and becomes sharp toward the upper side, And the guide cone

A guide plate which is erected and installed at a plurality of equally spaced intervals to prevent mixed flow at the time of suction of the fluid; And a fixing member for fixing the guide cone and the guide plate to the inlet side of the underwater axial flow pump.

The suction guide assisting device of the conventional underwater axial flow pump having such a structure is installed at the suction portion of the axial flow pump to prevent the cavitation generated in the fluid suction process, thereby improving the suction efficiency and performance of the pump.

However, the suction guide assisting device of the conventional underwater axial flow pump only prevents the cavitation phenomenon, and does not reduce the resistance of the fluid due to the forced rotation of the impeller, resulting in insufficient improvement of the suction performance.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to improve the suction performance by reducing the resistance of the fluid by previously circulating the fluid in accordance with the direction of the fluid pumped by the impeller. The present invention also provides a suction cone having a suction performance improved by a vortical flow generating blade which can be provided with a swirling flow generating blade.

According to an aspect of the present invention, there is provided a suction cone having suction performance improved by a swirl flow generating blade according to an embodiment of the present invention is provided with a swirl flow generating blade positioned below a suction port of a pump to guide movement of a fluid to be sucked A suction cone having improved suction performance, comprising: a cone body positioned at a lower portion of the suction port of the pump and having a smaller diameter from the lower end toward the upper portion to guide movement of the fluid; The fluid is rotated outside the cone body so as to rotate in accordance with the direction in which the impeller is rotated and is cut in a shape corresponding to the outer surface of the cone body so that the inner side thereof is close to the outer surface of the cone body, And a swing motor installed inside the cone body for rotating the swirl generating blades.

The swirl flow generating vane may further include a scraper portion formed to protrude laterally from the bottom of the cone body to scrape up sediments accumulated on the bottom of the corrugation.

And the swing motor may include a rotation controller for controlling the swirl generating blades to rotate in proportion to the rotational speed of the impeller.

An airtight seal hermetically sealing the space between the drive shaft of the swing motor and the cone body; and a seal provided on the drive shaft to prevent fluid from entering the swing motor when the fluid flows on the drive shaft, thereby preventing breakage of the swing motor And a fluid stopping plate.

And a spacing boss for supporting the pivoting motor at a distance from the floor of the cone main body to prevent damage to the pivoting motor when fluid flows into the cone main body.

And a cone bracket that connects the perimeter of the cone body and the periphery of the column pipe to which the pump or the pump is inserted.

The pump having the suction cone with improved suction performance by the swirling flow generating blades according to the embodiment of the present invention is characterized in that the suction cone is improved in suction performance by the swirling flow generating blades according to the above embodiment, A casing disposed at an upper portion of the suction cone, the suction port being guided by the cone body, the casing having a suction port through which the fluid flows and a fluid sucked through the suction port, an impeller installed inside the casing, And a pump motor for rotating the pump.

According to the present invention, since the fluid is guided and introduced by the cone body, the occurrence of turbulence is minimized to improve the suction performance, the swirl prevention blade is rotated, and the fluid is previously turned in the direction in which the fluid is rotated by the impeller, The suction performance can be improved.

In addition, a scraper portion is formed on the swirl flow prevention blade, so that the sediment can float along with the rotation to suck the fluid together with the sediment to remove the sediment.

Further, the swing controller controls the swing motor to be proportional to the rotational speed of the impeller, thereby minimizing the turning difference of the fluid, thereby improving the suction performance.

Further, a hermetic seal is provided in the shaft hole, a fluid blocking plate is provided in the drive shaft, and the swing motor is separated from the floor by the spacing boss, so that breakage of the swing motor due to immersion can be minimized.

1 is a perspective view illustrating a suction cone with improved suction performance according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of a suction cone with improved suction performance according to an embodiment of the present invention.
3 is a side sectional view of a suction cone with improved suction performance according to an embodiment of the present invention.
4 is a side cross-sectional view showing a pump having a suction cone with improved suction performance according to an embodiment of the present invention.
5 is a side cross-sectional view showing an enlarged view of a suction port portion of a pump provided with a suction cone with improved suction performance according to an embodiment of the present invention.

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

In the drawings, a suction cone 100 having improved suction performance by a swirling flow generating blade according to an embodiment of the present invention is shown to be applied to a double-axial axial flow pump. However, the present invention is not limited to the chorus flow pump, the underwater axial flow pump, And can be applied to or applied to all of the orifice pumps.

1 to 3, the suction cone 100 having improved suction performance by the swirling flow generating blade according to the embodiment of the present invention may include the cone body 110. FIG.

The cone body 110 can guide the inflow of the fluid so that the fluid to be sucked can be smoothly introduced into the suction port 211 of the pump 200.

The bottom of the cone body 110 may have a diameter similar to the diameter of the inlet 211 or may have a larger size. The cone body 110 may have a smaller diameter And may be formed in the shape of a cone or polygonal horn.

The outer surface of the cone body 110 may be formed to have a concave curved surface so as to be smoothly guided toward the suction port 211 so as to enter.

In addition, the cone body 110 may be hollow, and the lower portion of the cone body 110 may be closed by a plate-shaped body cover 115, A plurality of fastening holes may be formed in the body cover 115, and through holes may be formed at positions corresponding to the fastening holes of the body cover 115 so as to be fastened and fixed by bolts and nuts in a mutually overlapped state.

At this time, a body seal may be installed between the body cover 115 and the cone body 110 to prevent fluid from flowing into the cone body 110.

A shaft hole 111 protruding through a drive shaft, which will be described later, may be formed at an upper end of the cone body 110.

A plurality of spacing bosses 117 for separating the swing motor 130 from the floor may be formed on the main body cover 115.

Here, when the swing motor 130 is directly attached to the main cover 115, when the fluid flows into the cone main body 110, there is a fear that the swing motor 130 is locked in the fluid, However, if the swing motor 130 is installed apart from the separation boss 117, damage to the swing motor 130 can be prevented as long as the fluid does not rise up to the height of the separation boss 117 even if a part of the fluid is introduced.

As shown in FIGS. 1 to 3, the suction cone 100 having improved suction performance by the swirling flow generating blades according to the embodiment of the present invention may include the swirling flow generating blades 120.

The swirl flow generating vane 120 is swung by the rotation of the impeller 230 to be guided by the cone body 110 so as to easily suck the rotating fluid, have.

On the other hand, the vortical flow generating vane 120 is formed in the shape of a plate, and a center portion thereof can be rotatably coupled to the cone body 110.

The swirl flow generating vane 120 is formed in an incision shape corresponding to the outer surface of the cone body 110 so that the inside thereof is positioned close to the cone body 110, The projecting height can be minimized.

Here, the vortical flow generating vanes 120 may be formed to have the same length as the diameter of the suction cone 100 and not protrude outside the suction cone 100.

On the other hand, the swirl flow generating vane 120 may include a scraper portion 125.

The scraper portion 125 boils and floats the sediment accumulated on the bottom of the sump, and sucks the sludge together with the fluid into the suction port 211, thereby removing sediment accumulated in the sump.

The scraper portion 125 is formed to have a length protruding to the outside of the suction cone 100 so that the lower portion of the extended portion of the swirl flow generating vane 120 is shaped like a rake So that precipitates deposited in the collection can be scraped and lifted.

The scraper portion 125 may be formed at both ends of the swirling flow generating vane 120 and a shaft coupling portion to which the drive shaft of the swing motor 130 is coupled may be formed at a central portion of the swirling flow generating vane 120 .

The swirling flow generating vane 120 generates a swirling flow by rotating the fluid that is twisted and sucked at a preset angle with respect to the drive shaft like an impeller 230 to generate a suction force so that the suction port 211 of the pump 200 So that the fluid can be sucked in easily.

As shown in FIGS. 2 and 3, the suction cone 100 having improved suction performance by the swirl generating blades according to the embodiment of the present invention may include the swing motor 130.

The swirling motor 130 is installed inside the cone body 110 to rotate the swirling flow generating blades 120.

Meanwhile, the swing motor 130 may be implemented by an electric motor in which the drive shaft rotates by electricity, and the drive shaft may be connected to the speed reducer by a reducer so as to generate a rotational force greater than the rotational force of the swing motor 130.

The driving shaft of the swing motor 130 protrudes through the shaft hole 111 of the cone body 110 and the swirling flow generating vane 120 is coupled to the protruded portion of the driving shaft to generate the swirling flow generating vane 120 .

The swivel motor 130 may be disposed on the spacer boss 117 formed on the main cover 115 and spaced apart from the bottom of the main cover 115.

In addition, the swing motor 130 may include a swing controller.

The swing controller can control the swing motor 130 so that the swirling flow generating blades 120 rotate in proportion to the speed of the impeller 230 to generate a swirling flow.

Here, as the rotational speed of the impeller 230 is higher, the swirling flow must be swirled more quickly to minimize the impact due to the difference in rotational speed of the fluid.

The rotational speed of the impeller 230 may be higher than the rotational speed of the vortex flow generating vane 120 because the rotational speed of the vortex flow generating vane 120 and the impeller 230 are proportional to each other.

The swing motor 130 may be embodied as an underwater motor that is hermetically sealed to prevent inflow of fluid.

2 and 3, the suction cone 100 having improved suction performance by the swirl generating blades according to the embodiment of the present invention includes the hermetic seal 113 and the fluid stop plate 140 .

The airtight seal 113 is installed in the shaft hole 111 and can seal between the drive shaft and the shaft hole 111.

The airtight seal 113 may be formed of a material having elasticity such as urethane, rubber, silicone or the like so that the airtight seal 113 can be closely attached to the drive shaft. The airtight seal 113 may be realized by a known mechanical seal.

The fluid stop plate 140 is formed in the shape of a plate and prevents fluid introduced into the shaft hole 111 from being coupled to the drive shaft or flowing the fluid flowing through the drive shaft directly to the swing motor 130, It is possible to prevent breakage of the swing motor 130 due to the inflow of the swing motor 130. [

At this time, the fluid blocking plate 140 may have a circumference larger than the circumference of the driving motor 250 to prevent the fluid flowing into the bore hole 111 from being directly introduced into the swing motor 130, 140 may be formed at the end of the cone body 110 with a flow vane for flowing air.

When the fluid obstruction plate 140 is formed with a flow vane, the air inside the cone body 110 is circulated to circulate the air, so that the air heated by the heat generated by the swing motor 130 and the cone body 110, So that the temperature of the swing motor 130 is increased and the performance is prevented from being lowered.

2 and 3, the suction cone 100 having improved suction performance by the swirl generating blades according to the embodiment of the present invention may include a cone bracket 160.

The cone bracket 160 can fix the suction cone 100 to the casing 210 of the pump 200 or the suction port 211 of the column pipe into which the pump 200 is inserted.

The cone bracket 160 is formed in a bar shape and one end of the cone bracket 160 is screwed to the lower end of the cone bracket 160 and the other end of the cone bracket 160 is screwed around the suction hole 211, May be provided on the periphery of the cone body 110.

At this time, when the vortex generating vane 120 is formed to protrude to the outside of the cone body 110, the cone bracket 160 is formed in a "C" shape so as not to hinder the rotation of the vortex generating vane 120 It is possible.

4 and 5, a pump 200 having a suction cone 100 having an improved suction performance by a swirling flow generating blade according to an embodiment of the present invention includes a casing 210, a pump 200 A motor, and an impeller 230.

The casing 210 may have a suction port 211 through which the fluid is sucked and a discharge port 213 through which the sucked fluid is discharged. The impeller 230 may be rotatably installed in the casing 210.

The driving shaft 251 of the pump 200 may be connected to the impeller 230 to rotate the impeller 230.

The pump 200 motor may be installed inside the casing 210 or may be installed in the casing 210 by being wrapped in a motor casing 210 different from the casing 210.

The suction cone 100 having the suction performance improved by the swirling flow generating blades according to the embodiment can be coupled to the suction hole 211 by the cone bracket 160.

The operation and effects of the above-described respective structures will be described.

The suction cone 100 having improved suction performance by the swirling flow generating blade according to the embodiment of the present invention is provided with the swing motor 130 inside the cone body 110, 110 at the bottom of the boss 117.

The driving shaft of the swing motor 130 protrudes through the shaft hole 111 of the cone body 110. The swirling flow generating blades 120 are installed on the driving shaft of the swing motor 130, (111) is provided with a hermetic seal (113) to seal between the drive shaft and the shaft hole (111).

A fluid stopping plate 140 is installed on the driving shaft to prevent the fluid from being directly introduced into the driving motor 250 through the shaft hole 111. A blade for flowing air is formed at the end of the fluid stopping plate 140 do.

Further, the swing motor 130 is controlled by the swing controller so as to rotate in proportion to the rotational speed of the impeller 230.

The swirl flow generating vane 120 may be provided with a scraper portion 125 for floating sediment and the suction cone 100 may be installed on the suction port 211 of the pump 200 by the cone bracket 160 , And may be installed at the bottom of the collecting unit, which is a vertical lower portion of the suction port 211 of the pump 200, separately from the pump 200.

The pump 200 having the suction cone 100 improved in suction performance by the swirling flow generating blade according to the embodiment of the present invention is provided with the impeller 230 inside the casing 210 and the impeller 230, The suction force of the swirling flow generating blades according to the above embodiment is improved by the driving motor 250 coupled to the driving shaft 251 of the driving motor 250 and the suction port 211 of the casing 210 The suction cone 100 is coupled by the cone bracket 160. [

The pump 200 having the suction cone 100 having the suction performance improved by the swirling flow generating vane according to the embodiment of the present invention rotates the impeller 230 when the drive motor 250 starts, A suction force is generated in the suction port 211 of the casing 210 so that the fluid stored in the dust collecting compartment is guided and sucked into the suction cone 100 having improved suction performance by the swirling flow generating blades, Is discharged to the outside of the collector through the discharge port (213).

On the other hand, fluid that is guided by the suction cone 100 having improved suction performance by the swirling flow generating blades and sucked into the suction port 211 is guided along the outer surface formed by the curved surface of the suction cone 100, The suction force is improved by minimizing turbulence and cavitation at the suction port 211, thereby improving the lifting and efficiency of the pump.

At the same time, when the impeller 230 is rotated by the driving motor 250, the swing motor 130 is driven by the swing controller, and the swing motor 130 rotates the swirl generating blades 120 to rotate the impeller 230 The suction performance can be improved by reducing the resistance of the fluid by pivoting in advance the fluid sucked and pivoted according to the rotation.

On the other hand, when the scraper portion 125 is formed in the swirling flow generating vane 120, the swirling sediment is scraped up when the swirling flow generating vane 120 rotates, and the floated sediment is moved together with the fluid to the inlet 211 It may be inhaled to reduce the sediment of the house crystal.

The hermetic seal 113 is provided in the shaft hole 111 of the cone body 110 to protect the swing motor 130 from the inflow of the fluid and even if the fluid flows through the shaft hole 111 It is possible to prevent the fluid from being directly introduced into the swing motor 130 by the fluid blocking plate 140 and the fluid separated by the fluid blocking plate 140 is dispersed far away from the swing motor 130 by the centrifugal force, It is possible to prevent the motor 130 from being damaged.

Since the swivel motor 130 is positioned away from the floor by the separation boss 117 even if a part of the fluid is introduced, the swivel motor 130 can be prevented from being damaged as long as the fluid does not flow by the height of the separation boss 117 .

Accordingly, the pump 200 having the suction cone 100 improved in suction performance by the swirl generating blades according to the embodiment of the present invention is configured such that when the fluid flows, the fluid is guided to the outer surface of the cone body 110, It is possible to minimize the occurrence of turbulence and cavitation caused by the resistance of the fluid at the suction port 211 side of the pump 200 to improve the suction performance and to improve the suction performance of the impeller 230, the fluid is pre-swirled in the direction in which it is pivoted, and is introduced into the pump 200, thereby reducing the resistance of the fluid, thereby improving the suction performance.

In addition, the swirl flow generating vane 120 is provided with the scraper portion 125 to float the precipitate, thereby minimizing accumulation of deposits in the collection.

A hermetic seal 113 is provided between the shaft hole 111 of the cone main body 110 and the drive shaft to perform airtightness while fluid introduced into the shaft hole 111 by the fluid stop plate 140 is supplied to the swing motor The swirling motor 130 can be prevented from being damaged due to the direct inflow of the swirling motor 130 into the swirling motor 130. Even when the swirling boss 117 separates the swirling motor 130 from the floor, It is possible to prevent damage to the battery 130.

Further, the rotation speed of the swing motor is increased or decreased by the swing controller in proportion to the rotation speed of the impeller, thereby reducing the generation difference of the swirling flow, thereby improving the suction performance.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

100: Suction cone 110 that improves suction performance by vortex generating blades 110:
111: shaft hole 113: airtight seal
115: main body cover 117: spacing boss
120: swirl flow generating blade 125: scraper portion
130: Swing motor 140: Fluid blocking plate
160: Cone bracket
200: Pump with suction cone that improves suction performance by swirl flow generating blades
210: casing 211: inlet
213: discharge port 230: impeller
250: drive motor 251: drive shaft
300: Edit House

Claims (7)

A suction cone positioned at a lower portion of a suction port of a pump for improving suction performance by a swirl flow generating blade for guiding movement of a fluid to be sucked,
A cone body positioned at a lower portion of the suction port of the pump and having a smaller diameter from the lower end toward the upper end to guide the movement of the fluid,
The outer circumferential surface of the cone main body and the outer surface of the cone main body are arranged so that the inner surface of the cone main body rotates around the center of the cone main body and rotates outside the cone main body such that the fluid sucked and rotated rotates in accordance with the rotation direction of the impeller, A vortex flow generating blade which is cut into a corresponding shape to generate a vortical flow, and
And a swing motor installed inside the cone body for rotating the swirl generating blades,
The swirl flow generating blade
And a scraper portion protruding further from the bottom than the bottom of the cone body to scrape up sediments accumulated on the bottom of the collecting cores, wherein the swirling flow generating vanes improve the suction performance. delete The method according to claim 1,
The pivoting motor
And a rotation controller for controlling the swirling flow generating blades to rotate in proportion to the rotational speed of the impeller, wherein the swirling flow generating blades improve the suction performance. The method according to claim 1,
An airtight seal sealing the space between the drive shaft of the swing motor and the cone body,
And a fluid blocking plate installed on the driving shaft to prevent fluid from entering the swing motor when the fluid flows on the driving shaft to prevent breakage of the swing motor. Suction cone with improved performance. The method according to claim 1,
And a separation boss for separating the swing motor from the floor of the cone body to prevent damage to the swing motor when the fluid flows into the cone body. Suction cone with improved performance. The method according to claim 1,
And a cone bracket for connecting the periphery of the cone body and the circumference of the column pipe to which the pump or the pump is inserted, the concave bracket being attached to the cone body. A suction cone having improved suction performance by the swirling flow generating blade according to claim 1,
A casing having a suction port, which is positioned above the suction cone having an improved suction performance by the swirl generating blades and is guided by the cone body, through which a fluid flows and a fluid sucked through the suction port,
An impeller installed inside the casing, and
And a pump motor for rotating the impeller.

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