KR101586614B1 - Pump having a rotor blade having a vane angle coupling structure variable function - Google Patents

Abstract

The present invention relates to a pump having a rotor blade coupling structure with a blade angle variable function. The present invention rotates overall shafts of a plurality of blade units coupled to be rotated to a rotor body at constant intervals to reduce an initial start-up load current amount consumed for forward-rotating the rotor body where the blade units are provided at constant intervals in an initial stage and can freely control a flow rate through a blade angle variable unit varying an angle of the blade units.

Description

[0001] The present invention relates to a pump having a rotor blade coupling structure having a blade angle varying function,

The present invention relates to an apparatus and a method for controlling rotation of a plurality of vanes by rotating all the axes of a plurality of vanes coupled to a rotating body at equal intervals so as to vary the angle of a plurality of vanes, The present invention relates to a pump having a rotary vane coupling structure capable of reducing the amount of initial starting load current consumed for rotating the body in the normal or reverse direction and capable of varying the angle of the vane capable of controlling the automatic flow rate.

Generally, an underwater motor pump is installed in a water purification plant, a wastewater treatment plant, a basement where flooding is likely to occur, or a fish farm where a large amount of water is stored, for discharging water to the outside.
Such submersible motor pump is divided into submersible submersible motor pump, submerged submersible motor pump and ground type, and is waterproof because it is always in contact with water.
Here, the underwater motor pump mainly includes an electric motor unit; A water chamber coupled to a lower portion of the electric motor unit; And an impeller that is accommodated in a case coupled to a lower portion of the water chamber and is axially coupled to a lower portion of a driving shaft of the electric motor portion and rotates along a driving shaft of the electric motor portion. An underwater motor pump has been proposed in Korean Patent Registration No. 10-0968384, in which the motor unit can be cooled more efficiently and there is no fear that a safety accident such as a breakdown will occur due to overheating of the motor unit.
However, when the impeller of the submersible motor pump proposed in the above-mentioned Korean Patent Registration No. 10-0968384 is initially operated at an initial starting load of 9 times or more of the maximum electric current in the motor portion and the initial operation of the impeller is frequently occurred There is a problem that a large amount of electricity is consumed every time.

Korean Patent Registration No. 10-0968384

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 provide a wing angle adjusting unit which rotates all the axes of a plurality of wing portions rotatably mounted on a rotating body, Which has a rotary vane coupling structure capable of reducing the amount of initial starting load current consumed for initially and regularly rotating the rotary body having the wing portions at regular intervals and capable of varying the blade angle And the like.

According to an aspect of the present invention, there is provided an electronic device comprising: a rotating body having a space formed therein; A plurality of wings rotatably coupled to the rotating body at equal intervals by a shaft extending in the direction of the center of space of the rotating body; And a wing angle adjuster for changing the angle of the plurality of wing portions by rotating all the axes of the plurality of wing portions.

The wing angle adjusting unit includes a plurality of link members, each of which is provided inside the rotating body in a state where the shafts of the plurality of wings are coupled to one side, and the other side rotates to rotate all the shafts of the plurality of wings ; A moving plate that is axially coupled to one side, the other side, the front side, and the rear side of the other side of the plurality of link members and linearly moves inside the rotating body to rotationally move the other side of the plurality of link members; And a moving member for linearly moving the moving plate.

In addition, an extension shaft extending in the other direction of the plurality of link members is formed on one side, the other side, the front side and the rear side of the moving plate, and the other side of the plurality of link members is provided with a guide It is preferable that a slit is formed.

In addition, the moving member preferably comprises a cylinder to which the rod is connected to the moving plate.

A speed detector for detecting a rotational speed of the driving member for rotating the rotating body; And a controller for controlling the length of the rod in and out of the cylinder in accordance with the detected speed of the speed detector.

Further, the present invention provides a rotating body, comprising: a rotating body having a space formed therein; A plurality of wings rotatably coupled to the rotating body at equal intervals by a shaft extending in the direction of the center of space of the rotating body; And a wing angle adjusting unit for rotating all the axes of the plurality of wing units to vary the angle of the plurality of wing units.

The wing angle adjusting unit includes a plurality of link members, each of which is provided inside the rotating body in a state where the shafts of the plurality of wings are coupled to one side, and the other side rotates to rotate all the shafts of the plurality of wings ; A moving plate that is axially coupled to one side, the other side, the front side, and the rear side of the other side of the plurality of link members and linearly moves inside the rotating body to rotationally move the other side of the plurality of link members; And a moving member for linearly moving the moving plate.

In addition, an extension shaft extending in the other direction of the plurality of link members is formed on one side, the other side, the front side and the rear side of the moving plate, and the other side of the plurality of link members is provided with a guide It is preferable that a slit is formed.

In addition, the moving member preferably comprises a cylinder to which the rod is connected to the moving plate.

Here, the speed detecting unit detects the rotational speed of the driving member that rotates the rotating body; And a controller for controlling the length of the rod in and out of the cylinder in accordance with the detected speed of the speed detector.

Alternatively, when the driving member rotates the rotating body, the rods of the cylinder are drawn in and out in stages based on the detection signals of the angle detecting unit for detecting the angles of the plurality of vanes, It is preferable that the control unit is provided.

Furthermore, it is preferable that a control unit for varying the angles of the plurality of vanes according to an output signal of any one of the flow meter, the pressure gauge, and the water level sensing unit is provided while the rotating body is rotated by the driving member.

The present invention relates to an apparatus and a method for controlling rotation of a plurality of vanes by rotating all the axes of a plurality of vanes coupled to a rotating body at equal intervals so as to vary the angle of a plurality of vanes, It is possible not only to reduce the amount of initial starting load current consumed in rotating the body in the normal direction, but also to control the automatic flow rate.

1 and 2 are partially cutaway perspective views schematically showing a rotary vane coupling structure having a variable blade angle function according to an embodiment of the present invention,
FIG. 3 is a partially cutaway perspective view of FIG. 2,
4 is a perspective view schematically showing a state where the angle of a wing portion is varied,
5 is a side view sequentially showing a process of varying the angle of a wing portion,
FIG. 6 is a cross-sectional view schematically showing a pump provided with a rotary vane coupling structure having a variable blade angle function according to the present invention,
Figs. 7 and 8 are partial cross-sectional views of Fig. 6,
9 is a block diagram schematically showing the control state of the control unit.
FIG. 10 is a cross-sectional view schematically showing a pump provided with a rotary vane coupling structure having a variable blade angle function according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

1 and 2 are partially cutaway perspective views schematically showing a rotary blade coupling structure having a blade angle varying function, which is an embodiment of the present invention, and FIG. 3 is a partially cutaway perspective view of FIG.

As shown in FIGS. 1 and 2, the rotary vane coupling structure having the vane angle varying function, which is one embodiment of the present invention, includes a rotary body 10, a plurality of vanes 20 and a vane angle adjuster 30 .
First, a space 100 in which the blade angle adjusting unit 30 is installed is formed in the rotating body 10.
A plurality of vanes 20 are provided in the space 100 of the rotating body 10 so that the plurality of vanes 20 can be rotatably and counterclockwise rotated at regular intervals on the outside of the rotating body 10. [ And each of the shafts 210, which are horizontally coupled to the rotary body 10 at equal intervals, are formed while being horizontally extended in the direction of the center.
The plurality of wing portions 20, which are rotatably and rotatably coupled to the outer side of the rotary body 10 at regular intervals by the shaft 210, can be inclined at a predetermined angle in an oblique direction.
Next, the wing angle adjusting unit 30 rotates both the axes 210 of the plurality of wing portions 20 in the forward and reverse directions, thereby varying the vertical inclination angle? Of the plurality of wing portions 20.

FIG. 4 is a perspective view schematically showing a state where the angle of a wing portion is varied, and FIG. 5 is a side view sequentially showing a process of varying the angle of a wing portion.

3 to 5, the blade angle adjusting unit 30 may include a plurality of link members 310, a moving plate 320, and a moving member 330 .
3, the plurality of link members 310 are coupled to the rotating body 10 (see FIG. 3) in a state where the shafts 210 of the plurality of wing portions 20 are coupled to one side of the plurality of link members 310, Respectively.
An insertion slit 312, which may be formed in a polygonal shape such as a triangle, a rectangle, a pentagon, or a hexagon, may be formed on one side of the plurality of link members 310.
The cross sectional shape of the insertion portion of the shaft 210 of the plurality of wing portions 20 inserted into the insertion slit 312 formed at one side of the plurality of link members 310 corresponds to that of the insertion slit 312 Or the like.
The other side of the plurality of link members 310 can be rotated in the vertical direction of the plurality of link members 310 to rotate all the axes 210 of the plurality of vanes 20 in normal and reverse directions.
The other side of the plurality of link members 310 may be axially coupled to one side, the other side, the front side and the rear side of the moving plate 320.
The moving plate 320 may be linearly moved in the vertical direction of the rotating body 10 inside the rotating body 10 to vertically rotate the other side of the plurality of link members 310.
In order to facilitate smooth upward and downward movement of the moving plate 320, the moving plate 320 is horizontally extended to one side, the other side, the front side and the rear side of the moving plate 320, An extension shaft 321 coupled to the other side of the plurality of link members 310 may be formed so as to penetrate the other side of the link member 310, The guide slit 311 in which the extension shaft 321 of the plate 320 is accommodated may be extended from one side of the plurality of link members 310 to the other side of the plurality of link members 310 by a predetermined length have.
5, the moving member 330 may be a cylinder to which the rod 331 is connected to the moving plate 320 to vertically move the moving plate 320 in a straight line.
A cylinder constituting the moving member 330 may be provided in a lower direction of the moving plate 320 and a rod 331 of the cylinder constituting the moving member 330 may be formed by vertically moving the center of the moving plate 320 And can be coupled to the moving plate 320 in a penetrating manner.
The upper portion of the moving plate 320 and the lower portion of the moving plate 320 are fixed to the rod 331 that is coupled to the center of the moving plate 320 by bolts, And a plate member 332, which may be formed in a shape or the like, may be horizontally provided.
The moving member 330 may be an electric cylinder or the like, but the present invention is not limited thereto. The cylinder may be a hydraulic cylinder having a low residual rate, and the like.
As shown in FIG. 5, when the rod 331 of the cylinder constituting the moving member 330 descends and is gradually drawn into the cylinder, the moving plate 320 is gradually lowered and is inclined at a predetermined angle. The vertical inclination angle alpha of the wing portion 20 inclined in the direction of the rotation of the rotary body 10 can be gradually relaxed as shown in FIG. The resistance of the air to the wing portion 20 is relatively reduced, so that the rotating body 10 can be smoothly rotated in the normal direction even at a low power consumption at the beginning.

FIG. 6 is a cross-sectional view schematically showing a pump provided with a rotary blade coupling structure having a variable blade angle function according to the present invention, and FIGS. 7 and 8 are partial cross-sectional views of FIG.

As shown in FIGS. 6 to 8, the pump includes a rotary body 10, a plurality of wing portions 20, a plurality of wing angles A control unit 30, a casing 40, and a driving member 50.
The rotating body 10, the plurality of wing portions 20 and the wing angle adjusting portion 30 are provided inside the casing 40. Particularly, A cylinder constituting the moving member 330 of the vane angle adjusting unit 30 is accommodated in the lower portion of the casing 40 so that a cylinder constituting the moving member 330 of the vane angle adjusting unit 30 is fixed A cover member 410 may be provided.
The cylinder body 333 of the cylinder constituting the moving member 330 may be fixed in various ways such as bolt-fixing to the inner lower side of the cover member 410.
The rotating body 10 may be rotatably and rotatably mounted on the cover member 410.
A support vane 420 for supporting the cover member 410 may be radially formed between the outer surface of the cover member 410 and the inner surface of the casing 40 at regular intervals.
The driving member 50 is fixed to the casing 40 in a state where the driving shaft 510 of the driving member 50, which may be an electric motor or the like, is fixed to the upper portion of the rotating body 10, And the driving shaft 510 of the driving member 50, which may be an electric motor or the like, can rotate the rotating body 10 in normal and reverse directions.

9 is a block diagram schematically showing the control state of the control unit.

Next, as shown in FIG. 9, a speed detector 60 and a controller 70 may be further provided.
The speed detecting unit 60 is provided on the driving shaft 510 of the driving member 50 and rotates to detect the normal and reverse rotational speeds of the driving shaft 510 of the driving member 50 for rotating the rotating body 10 in normal and reverse directions. A speed sensor or an encoder.
The controller 70 may be a display unit such as a touch panel.
The control unit 70 receives power from the power supply unit 710 according to the normal and reverse rotational speeds of the driving shaft 510 of the driving member 50 detected by the speed detecting unit 60, The lead-out length of the rod 331 drawn to the outside of the cylinder and the lead-in length of the rod 331 drawn into the cylinder can be controlled.
For example, the control unit 70 may be provided with a memory unit that stores the length of the rod 331 in and out, corresponding to the normal and reverse rotational speeds of the driving shaft 510 of the driving member 50.
The operator can input the forward and reverse rotation speeds of the driving shaft 510 of the driving member 50 by operating a display unit such as a touch panel constituting the control unit 70. The control unit 70 controls the driving shaft 510 Output length of the rod 331 corresponding to the normal / reverse rotation speed of the cylinder 331 can be extracted from the memory unit and the rod 331 of the cylinder can be introduced and released.
As the rod 331 is drawn into the cylinder, the up-and-down inclination angle? Of the wing 20 can be gradually relaxed. As a result, a small amount of water or the like The fluid can be introduced at a low speed.
As the rod 331 is drawn out to the outside of the cylinder, the moving plate 320 gradually rises and the vertical inclination angle? Of the wing portion 20 gradually increases, So that a large amount of water such as water can be introduced into the casing 40 at a high speed.
Particularly, when the driving member 50 is initially operated, the moving unit 330 is controlled by the control unit 50 so that the wing unit 50, which is inclined at a predetermined angle in a diagonal (/ The resistance of the air and the fluid to the wing portion 20 is relatively reduced during the initial and reverse rotation of the rotary body 10 so that the rotary body 10 can be reduced in power consumption It is possible to smoothly rotate forward and backward more smoothly at the beginning.
Next, as another example, an angle detecting unit 80 for detecting the up-and-down inclination angle [alpha] of the plurality of vanes 20 during the initial driving of the driving member 50 for rotating the rotating body 10 in the normal and reverse directions The rod 331 of the cylinder constituting the moving member 330 is drawn in and out of the set portion for a predetermined period of time set by a timer or the like and the angles of the plurality of the wing portions 20 are changed stepwise The control unit 70 may be provided with a control unit 70. [
The angle detection unit 80 may be an angle sensor provided in the plurality of vanes 20.
Alternatively, the angle detector 80 may be a displacement sensor LVDT for measuring the change in length of the rod 331 of the cylinder in stages, and the controller 70 may control the load The vertical inclination angle alpha of the plurality of vanes 20 can be automatically calculated according to the change of the length of the blade 331.
When the rod 331 of the cylinder is drawn into the cylinder according to the detection signal of the angle detector 80 and the wing 20 is in a relaxed state, The rod 331 of the cylinder can be drawn out stepwise in the upward direction of the cylinder for a time set in the setting unit, So that it can be gradually tilted at an angle.

FIG. 10 is a cross-sectional view schematically showing a pump provided with a rotary vane coupling structure having a variable blade angle function according to the present invention.

Next, in another example, in a state where the rotating body 10 is rotated in the forward and reverse directions by the driving member 50, the control unit 70 controls the flow rate of the fluid to be measured by the flow meter 90, the pressure gauge, The angle of the plurality of vanes 20 can be varied according to one output signal.
The control unit 70 may be set to one of a reference flow rate value, a reference pressure value, and a reference water level value.
As shown in FIG. 10, the casing 40 may be fixed in various ways such as bolt-fixing to an inner lower side of the inflow pipe 7, which is formed by extending a predetermined length in the vertical direction.
A guide pipe 8 connected to the inflow pipe 7 communicating with the inflow pipe 7 is horizontally extended to a predetermined length in the outer direction of the inflow pipe 7 at an upper portion of the inflow pipe 7 .
The other side of the guide pipe 8 is connected to the upper side of the inflow pipe 7 in such a manner that the other side of the guide pipe 8 communicates with the fluid storage tank in which fluid such as water is stored, May be connected to a storage tank.
Fluids such as water flowing into the casing 40 can be sequentially passed through the inflow pipe 7 and the guide pipe 8 to be supplied to the fluid storage tank.
The flow pipe 7 or the guide pipe 8 may be provided with a flow meter 90 for measuring the flow rate of fluid such as water passing through the inflow pipe 7 or the guide pipe 8.
Alternatively, the inlet pipe 7 or the guide pipe 8 may be provided with a pressure gauge for measuring a pressure value of fluid such as water passing through the inlet pipe 7 or the guide pipe 8.
The control unit 70 compares the flow rate measured by the flow meter 90 or the pressure measured by the pressure gauge with the reference flow rate or reference pressure value set in the controller 70, Can be varied.
When the flow rate value measured by the flow meter 90 or the pressure value measured by the pressure gauge is less than or equal to the reference flow rate value or the reference pressure value, the rod 331 of the cylinder, under the control of the controller 70, The angle of inclination? Of the plurality of wings 20 gradually increases so that the wings 20 are inclined in the diagonal direction so that the inlet pipe 7 or the guide pipe A large amount of fluids such as water can be introduced into the inside of the water tank 8.
When the flow rate value measured by the flow meter 90 or the pressure value measured by the pressure gauge exceeds the reference flow rate value or the reference pressure value, the rod 331 of the cylinder under the control of the control unit 70, The angle of inclination? Of the plurality of vanes 20 is gradually reduced so that a small amount of air flows into the inlet pipe 7 or the guide pipe 8 The fluid such as water can be introduced.
Level sensor may be installed on the inner surface of the fluid storage tank to sense the level of the fluid such as water stored in the fluid storage tank.
When the measured water level measured by the water level sensing unit 100 is equal to or lower than the reference water level value, the rod 331 of the cylinder can be gradually drawn upward in the direction of the cylinder under the control of the controller 70, The tilting angle? Of the plurality of wings 20 gradually increases and the wings 20 are inclined in the diagonal direction so that a large amount of water is supplied to the inside of the inflow pipe 7 or the guide pipe 8 May be introduced into the fluid storage tank.
When the measured level value measured by the water level sensing unit 100 exceeds the reference water level value, the rod 331 of the cylinder can be gradually introduced into the cylinder under the control of the controller 70, So that a small amount of water or the like flows into the inflow pipe 7 or the guide pipe 8 to flow into the inflow pipe 7 or the guide pipe 8, May be moved into the fluid storage tank.
The present invention constructed as described above is capable of rotating all the shafts 210 of a plurality of the wings 20 rotatable at equal intervals on the rotating body 10 by rotating the wings 20 in the forward and reverse directions, It is possible to reduce the amount of initial starting load current consumed for rotating the rotating body 10 in the initial and reverse directions at which the plurality of wing portions 20 are equally spaced by the wing angle adjusting portion 30 for varying the angle There is also an advantage of being able to control the automatic flow rate as well.

10; Rotating body, 20; Wing parts,
30; Wing angle adjustment part.

Claims (12)

A rotating body having a space formed therein;
A plurality of wings rotatably coupled to the rotating body at equal intervals by a shaft extending in the direction of the center of space of the rotating body;
A plurality of vanes are provided in the interior of the rotary body in a state where the shafts of the plurality of vanes are coupled to one side so as to vary the angle of the plurality of vanes by rotating all the axes of the plurality of vanes, A plurality of link members for rotating both the axes of the wing portions; and a plurality of link members for axially coupling the other side of the plurality of link members to one side, the other side, the front side and the rear side, A wing angle adjusting unit comprising a moving plate for linearly moving the moving plate and a moving member for moving the moving plate linearly;
And a casing in which the rotating body, the plurality of vanes and the vane angle adjuster are provided,
Wherein the moving member is composed of a cylinder having a rod vertically penetrating the moving plate located in a lower direction of the moving plate, the cylinder body of the cylinder is fixed to an inner lower side of the casing, And a plate member positioned in an upper direction and a lower direction of the rotary member, respectively.
The method according to claim 1,
And a rod of the cylinder constituting the moving member is coupled to the moving plate by a bearing.
The method according to claim 1,
Wherein the cylinder body of the cylinder constituting the moving member is fixed to an inner lower side of the cover member while being accommodated in a cover member provided at a lower side of the casing. Equipped pump.
The method according to claim 1,
An extension shaft extending in the other direction of the plurality of link members is formed on one side, the other side, the front side and the rear side of the moving plate,
And a guide slit is formed on the other side of the plurality of link members to receive an extension shaft of the guide plate.
The method according to claim 1,
A speed detector for detecting a rotational speed of a driving member for rotating the rotating body;
And a controller for controlling the length of the rod in and out of the cylinder in accordance with the speed detected by the speed detector.
The method according to claim 1,
And a control unit for controlling the angle of the plurality of vanes by varying the angle of the plurality of vanes when the rod of the cylinder is drawn in and out stepwise on the basis of a detection signal of an angle detecting unit for detecting an angle of the plurality of vanes during initial driving of the driving member for rotating the rotating body Wherein the control unit is provided with a rotating blade coupling structure having a blade angle varying function.
The method according to claim 1,
And a control unit for varying the angle of the plurality of vanes according to an output signal of the flow meter, the pressure gauge, and the water level sensor while the rotating body is rotated by the driving member. Wherein the pump has a rotating blade coupling structure.
The method of claim 3,
The rotating body is rotatably provided on the cover member,
And a support blade for supporting the cover member is formed between the outer surface of the cover member and the inner surface of the casing. delete delete delete delete

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