KR101761699B1 - Pump assembly - Google Patents

Abstract

The present invention relates to a vertical pump assembly for a power generator capable of lifting up the water in a bottom reservoir and supplying the water to a generator. More particularly, the present invention relates to a pump assembly including a housing for raising and discharging inflow water, When the pumping means composed of the rotating shaft and the plurality of vane members is rotated by the driving means, the water is drawn up in accordance with the flow of the air currents formed by the vane members, and even when carrying a heavy weight water, The present invention relates to a vertical pump assembly for a power generator, which can discharge a large amount of water at a time and which can be selected by a user in accordance with a location where the housing is to be installed.

Description

Vertical Pump Assembly for Power Generation {PUMP ASSEMBLY}

The present invention relates to a vertical pump assembly for a power generator capable of lifting up the water in a bottom reservoir and supplying the water to a generator. More particularly, the present invention relates to a pump assembly including a housing for raising and discharging inflow water, When the pumping means composed of the rotating shaft and the plurality of vane members is rotated by the driving means, the water is drawn up in accordance with the flow of the air currents formed by the vane members, and even when carrying a heavy weight water, The present invention relates to a vertical pump assembly for a power generator, which can discharge a large amount of water at a time and which can be selected by a user in accordance with a location where the housing is to be installed.

A pump is a device that transports liquid or gaseous fluid through a pipe by a pressure action, or pushes fluid in a low pressure container through a pipe into a high pressure container. Such pumps include reciprocating pumps, rotary pumps, centrifugal pumps, axial flow pumps, and friction pumps. The centrifugal pumps transport or pump fluids using centrifugal force generated by rotating one or more impellers in a closed casing do.

When the impeller rotates, a centrifugal force is generated. When the fluid in the center part is discharged to the outside by the centrifugal force, the pressure in the center part is lowered and becomes close to the vacuum. Thus, the fluid is sucked through the absorption pipe toward the center portion of the impeller. In this way, the fluid is continuously sucked and pressed by the pressure. This is why the inlet of the centrifugal pump is directed towards the center of the impeller.

The centrifugal pump is widely used in the industrial field because it can rotate at a high speed, is small in size and light in weight, is simple in structure, easy to handle, and has high efficiency. In other words, it is the most used among the pumps used in industries such as ship watering, water supply and sewage, mining, and chemical industry.

Such prior art is disclosed in Korean Patent Laid-Open No. 10-2015-0007436 entitled "

The above-described prior art is characterized in that it comprises at least one water hole formed in the pump for discharging the water droplets scattered by the non-acid pump to the outside of the pump, The present invention proposes a submerged water immersed vertical pump capable of achieving a sealed sealing with a simple structure.

Also, in the prior art, there is a " vertical pump ", registered patent No. 10-0656500,

The above-mentioned prior art has a motor provided with a rotation motor, a motor support provided below the rotation motor to support the rotation motor, a case provided under the motor support to suck and discharge the fluid, A rotating shaft which is passed through a center portion and is rotated by a rotational power of the rotating motor; and a rotating shaft which is coupled to a lower end portion of the rotating shaft and rotates by rotation of the rotating shaft to suck and discharge the fluid, And a vertical pump including an entire backflow prevention rotating body for guiding.

Another conventional technique is disclosed in Korean Patent Application No. 10-2009-0108785 entitled " Vertical Pump Device with Nonsilicon Structure "

In the conventional art, an impeller and a motor installed in a housing are connected to a shaft at a lower portion of the pump, and a backflow pressure distribution of a fluid flowing backward along an axis is provided between the motor and the housing of the pump. A first pressure distributor having first and second chambers for the inside and the outside of the housing, and a second pressure distributor having third and fourth chambers in the housing inside and outside, And an impeller having an output is coupled to the shaft.

Further, as a prior art, Patent No. 10-0953260 entitled " Vertical multi-stage pump "

The prior art includes a lower casing formed with a fluid inlet connected to one side thereof and having an inner central upper portion opened, an impeller for covering the opened upper center portion of the lower casing and stacked in a multi- A plurality of pumping portions provided with a fluid outlet at the predetermined casing and a plurality of impellers of the respective pumping portions and a motor shaft are axially coupled to each other, And a pumping motor for pumping upwards in a stepwise manner in the pumping section.

However, the above-mentioned conventional techniques are directed to a pump for simply raising a fluid, which lifts a fluid by using a centrifugal force generated by a rotational force of an impeller or a motor, and is easy to vertically lift a fluid having a small area according to the weight per unit area of the fluid However, when the unit area is increased, there is a limit to lift the fluid as the weight of the fluid increases, which makes it difficult to pump a large amount of fluid.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art,

A pump assembly comprising a housing into which water can be introduced and discharged upward,

The water is raised along the spiral wing member through the pumping means including the rotating shaft provided in the housing and the wing member spirally coupled to the rotating shaft and the driving means rotating the pumping means, Which can discharge a large amount of water at one time.

The vertical pumping assembly may include a lower body, an intermediate body, and a plurality of intermediate bodies. The vertical body may include a plurality of intermediate bodies. The purpose is to provide.

In order to accomplish the above object, a vertical power generation pump assembly according to the present invention includes:

A pumping means including a rotating shaft and a plurality of wing members linearly coupled to the rotating shaft to raise the water by rotation;

Driving means for rotating the pumping means, the driving means being connected to the rotating shaft;

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When the pumping means rotates, the water rises to the upper portion of the housing along the wing member by rotation of the wing member.

As described above, the vertical pump assembly for power generation according to the present invention is a pump assembly comprising a housing for inflow and discharge of water,

A pumping means including a rotating shaft provided in the housing and a plurality of wing members coupled to the rotating shaft, and a driving means for rotating the pumping means, wherein water is raised along the wing member by rotation of the wing member, Therefore, even when water having a heavy weight is transported, it is possible to disperse the weight so as to cover the weight, so that a large amount of water can be raised at a time.

In addition, since the housing is composed of the lower body, the intermediate body, and the upper body, the intermediate body can be selectively coupled to a plurality of the bodies so that the height of the entire housing can be adjusted according to the place to be installed, There is an effect that it is not received.

Further, the rotating shafts connected to each other can be coupled using the connecting means, so that power can be transmitted to the pumping means connected to each other through one driving means. In connecting the rotating shafts to each other, a separate fixing device There is no need to improve the assembling convenience.

In addition, water stored in a bottom reservoir such as a water tank can be transferred and reused, and water can be appropriately supplied to the generator.

1 is a schematic cross-sectional view of a power generation vertical pump assembly according to the present invention;
2 is a perspective view of a pumping means of a vertical power generation pump assembly according to the present invention;
3 is a schematic side view of a pumping means of a vertical power generation pump assembly according to the present invention
4 is a view showing a modification of the vertical power generation pump assembly according to the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

While the present invention has been described in connection with certain embodiments, it is obvious that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the drawings, the same reference numerals are used for the same reference numerals, and in particular, the digits of the tens and the digits of the digits, the digits of the digits, the digits of the digits and the alphabets are the same, Members referred to by reference numerals can be identified as members corresponding to these standards.

In the drawings, the components are expressed by exaggeratingly larger (or thicker) or smaller (or thinner) in size or thickness in consideration of the convenience of understanding, etc. However, It should not be.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the term " comprising " or " consisting of ", or the like, refers to the presence of a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

The vertical pump assembly A for power generation according to the present invention is a pump assembly A comprising a housing 10 formed with an inflow path 131 and a rising path 121 and a discharge path 111, The pumping means 20 for raising the water and the driving means 30 for transmitting the power to the pumping means 20, as shown in FIG.

More specifically, the housing 10 is provided with an inflow passage 131 through which the water flows, A rising path 121 for raising the water and a discharge path 111 for discharging the water. More specifically, the housing 10 is assembled so as to be variable in length depending on the installation location, An intermediate body 12 fastened to the upper portion of the lower body 13 and an upper body 11 fastened to the upper portion of the intermediate body 12 as shown in FIG.

First, the lower main body 13 is formed with an inflow path 131 through which water flows. The inflow path 131 has a shape similar to a cylindrical shape forming the inflow path 131, and a first flange portion 133 are formed. The lower portion of the lower main body 13 is formed with an enlarged portion 135 having a larger diameter than that of the upper portion. This is in accordance with the diameter of the wing member 25 of the pumping means 20 described later. .

The intermediate body 12 is coupled to the upper portion of the lower body 13 such that the intermediate body 12 has an upward path 121 in which the water rising from the lower body 13 can rise, And a second flange portion 122 and a third flange portion 123 are respectively provided at the lower end and the upper end.

An upper body 11 is coupled to an upper portion of the intermediate body 12. The upper body 11 is formed with a discharge path 111 through which water is discharged upwardly, (113) is formed.

As a result, when the lower main body 13, the intermediate main body 12 and the upper main body 11 are engaged, the first flange portion 133 and the second flange portion 122 are fastened, The second flange portion 123 and the fourth flange portion 113 are coupled to each other so that they can be assembled in a prefabricated manner. The coupling method can be firmly combined by using a separate fastening bolt 15, It is preferable that the length of the entire housing 10 can be adjusted in accordance with the length to be installed so that a plurality of the plurality of grooves 12 may be selected and coupled.

Further, it is preferable to further include a packing member 17 between the respective flange portions so as to prevent the water to be transferred from leaking out,

It is preferable to further include a reinforcing member 19 that can be inserted between the respective bodies so as to further improve the engaging force, but this is merely an example and should not be construed as limiting the scope of the right.

In addition, a discharge passage 111 is formed at one side of the upper body 11 to discharge the raised fluid. The discharge passage 111 is provided with an opening / closing valve to open or close the discharge passage 111, It is preferable to make it possible to close it,

It is preferable that another discharge passage 111 is formed on one side of the intermediate body 12 so that water which is raised to a desired height can be discharged. To be opened or closed.

The vertical pump assembly A according to the present invention is provided with a driving means 30 for rotating a pumping means 20 to be described later. And a drive shaft 31 provided in the upper portion of the housing 10 and a drive shaft 33 provided in the drive motor 31 is formed to penetrate into the center of the interior of the housing 10, So that the rotating shaft 21 can be rotated by the rotation of the driving motor 31. As shown in Fig.

The vertical pump assembly A for power generation according to the present invention further comprises a pumping means 20 for lifting a large amount of water upward.

The pumping means 20 will be described in more detail with reference to FIGS. 1 to 3,

The pumping means 20 includes a rotating shaft 21 provided in the housing 10 and a plurality of wing members 25 provided in a serpentine shape on the outer surface of the rotating shaft 21.

More specifically, the pumping means 20 is provided in each of the housing 10, specifically, the lower main body 13, the intermediate main body 12, and the upper main body 11, A plurality of wing members 25 of the wing members 25 are preferably provided to form a group of four wing members 25 so that each wing group 23 25) are spaced apart from each other by a predetermined distance. Preferably, the lower main body 13 is provided with one wing group 23 and the intermediate main body 12 is provided with two or more wing groups 23, And at least one wing group 23 is formed in the upper body 11. The number of the wing groups 23 can be selectively formed according to the diameter and the size of the housing 10, Should not be construed as limiting.

For convenience of explanation, the pumping means 20 provided in the intermediate body 12 will be described concretely. However, for convenience of explanation, the housing 10 will be referred to as the upper body 11 and the lower body 13), and the scope of the right should not be construed as limiting.

The rotating shaft 21 of the pumping means 20 is coupled to the housing 10. The rotating shaft 21 is formed in the center of the housing 10 in the longitudinal direction, And is fixed to the upper portion and the lower portion of the body 10 via the rotation inducing member 211, respectively.

The rotation inducing member 211 may be formed in various shapes such as a bearing and may be fixed to a central portion of the housing 10 so that the rotation shaft 21 can rotate when the driving motor 31 operates. consist of.

A plurality of wing members 25 are provided in a serpentine shape on a rotating shaft 21 capable of idling. Specifically, the wing members 25 include first to fourth wings 252 and 253, The first to fourth wings 252 and 254 may be formed to be spaced apart from each other, and the first to fourth wings 252 and 255 may include a plurality of wing groups 23, (253), (254) and (255) are also configured to be spaced apart from each other to form a water feed path (251) between the wing feed paths (251).

Before describing the respective wing members 25 in detail, the wing group 23 is provided in the lower main body 13, the intermediate main body 12 and the upper main body 11, The wing group 23 of the main body 13 is formed to be larger in diameter than the wing group 23 of the intermediate body 12 and the upper body 11 so that a larger centrifugal force can be formed to raise the water for the first time.

In addition, due to such a difference in diameter, the lower body 13 is provided with the enlarged portion 135, and as the diameter decreases toward the upper portion, the upward pressure is increased and the water is easily raised.

The wing member 25 is formed of a plurality of wing groups 23 and the wing group 23 is formed of first to fourth wings 252, 253, 254, and 255,

As shown in the drawing, each of the first to fourth wings 252, 253, 254, and 255 has its starting point rotated by 90 degrees with respect to a plane, and as a result, So as to be able to wind one rotation of the rotary shaft 21.

The wings are inclined in an oblique direction from the rotary shaft 21 so as to raise water by rotation and are formed between the first to fourth wings 252, 253, 254, and 255 As the water rises along the surface of the wing member 25 through the water conveyance path 251, it is possible to raise a large amount of water with a higher efficiency than that of using the conventional centrifugal force to raise the water have.

In addition, the adjacent rotary shafts 21 can be interlocked with each other in accordance with the housing 10 connected in a multi-stage as described above. To this end, a connecting member 27 is provided on the upper and lower portions of the rotary shaft 21, And the adjacent lower rotary shafts 21 can be interlocked with each other.

More specifically, the connecting member 27 is provided at the upper portion and the lower portion of the rotating shaft 21 and has a cylindrical shape so as to be fitted to the end of the rotating shaft 21, 27 are formed at the ends of the teeth 27 so that the pair of connecting members 27, preferably a pair of tooth connecting portions 271 are engaged with each other to be engaged, So that the convenience of assembly can be improved.

Further, although four wings are illustrated as forming one wing group 23 in the drawings, it is also possible to have more wings, and the scope of the right wing should not be construed to be limited.

4 is a view showing a modification of the vertical power generation pump assembly A according to the present invention. In order to adjust the length of the discharge path 111 of the water according to the installation environment, Further comprises a length adjusting means (H).

Each of the constitutions will be described in more detail with reference to the drawings. First, in the housing 10, the length of the first powder H1 and the length of the second powder H2 inserted in the first powder H1 The total length of the length adjusting means H is changed according to the degree of protrusion of the second powder H2 from the first powder H1 through the means H, So that the length of the guide groove 111 can be changed.

More specifically, the first powder H1 is provided with an interpolation unit H11, and the second powder H2 is inserted into the interpolation unit H11 to be protruded to one side of the first powder H1 And an inner protrusion H13 protruding inward is provided in the first powder H1 to prevent the second powder H2 from completely disengaging from the first powder H1, The powder H2 is preferably provided with a locking protrusion H21 protruding outward so as to be caught by the inner protrusion H13.

The length adjusting means H includes the first powder H1 and the second powder H2. The length adjusting means H includes a through hole H40 provided in the first powder H1, A moving hole H30 provided in the second powder H2 and a moving member H30 passing through the passing hole H40 and moving along the moving hole H30, (H50).

The second powder H2 is provided with a moving hole H30. The moving hole H30 includes an inclined portion H31 inclined in an oblique direction, And a vertical portion H33 extending in the inclined portion H31 and configured in a vertical direction and the inclined portion H31 is formed in the opposite direction again in the vertical portion H33, And the vertical portions H33 are formed as a single set and are arranged in a zigzag shape by being provided a plurality of times.

Further, the moving hole H30 may be formed in the shape of a hole or a groove, and the scope of the right should not be limited.

In addition, the first powder H1 is provided with a through hole H40. The through hole H40 has a first hole H41 formed in one direction and a second hole H41 communicating with both sides of the first hole H41 And a second hole H43 and a second hole H44, which are provided in the other direction, so that the shape of the second hole H43 is 'H'.

The moving member H50 is further provided with a moving member H50 that passes through the through hole H40 and is fastened to the moving hole H30. The body member H50 includes a body member H53 and a ball bearing H51 provided at the end of the body member H53 and a pull member H55 provided at the other end.

More specifically, a ball bearing H51 is provided at the end of the body member H53. The ball bearing H51 smoothly moves the moving member H50 more than when the moving member H50 moves in the movement hole H30. And a ball bearing insertion portion H533 is provided at an end of the body member H53 to seat the ball bearing H51. That is, the ball bearing insertion portion H533 is provided to cover at least half of the ball bearing H51 to prevent the ball bearing H51 from being detached, so that the ball bearing H51 in the ball bearing insertion portion H533 By freely rotating, the flexibility of movement can be improved.

A handle engaging portion H531 is further provided at the opposite end of the body member H53 and the handle member H55 is engaged with the handle engaging portion H531 to form one moving member H50 do.

More specifically, the handle insertion portion H531 and the body insertion portion H551 provided on the handle member H55 are coupled through a screw connection. When the handle member H55 is rotated by the screw engagement, This structure is described below in more detail when explaining the operation of the shifting member H50.

According to the above-described structure, the length of the first powder H1 is adjusted by controlling the degree of protrusion of the second powder H2. The operation of the second powder H2 will be described in detail with reference to an embodiment.

When the shifting member H50 is moved along the first hole H41 of the through hole H40 through the through hole H40 and is fastened to the moving hole H30, And the second powder H2 is raised by the inclined portion H31 (inclined portion H31 having an inclination raised in one direction). When the shifting member H50 is moved after the first hole H41 is moved, the shifting member H50 moves again along the inclined portion H31 that has been moved forward to return the second powder H2 to the original position Problems can arise. In order to solve this problem, a second hole H43 and a second hole H44 are provided on both sides of the first hole H41, and the moving member H50 is connected to the second hole H43, The moving member H50 is further raised by the vertical portion H33 of the moving hole H30 and when the moving member H50 is lowered again after this elevation, The moving member H50 is naturally moved to the next inclined portion H31 of the moving hole H30 and when the moving member H50 is moved in the opposite direction again, the moving member H50 moves along the second inclined portion H31, The two powder (H2) is configured to rise again.

That is, when the moving member H50 moves along the first hole H41 of the through hole H40, the moving member H50 moves along the inclined portion H31 of the moving hole H30, And moves along the second and second holes H44 of the through hole H40 by moving along the vertical portion H33 of the moving hole H30 to continuously supply the second powder H2. The first powder H2 can be raised from the first powder H1 and the moving member H50 can be moved by moving the second powder H2 when the second powder H2 is lowered.

In order to achieve this, a separate fixing device is required to fix the second powder H2 whose length has been adjusted. To this end, in the present invention, the holding member H55 is provided with a fixing flange H553, And a fixing groove H46 to which the fixing flange H553 is fitted.

More specifically, the handle member H55 is provided with a fixing flange H553 at an edge thereof, and the fixing flange H553 is bent in the direction of the body member H53.

In addition, the fixing groove H46 has a groove or a ball shape having a semicircular shape at both ends of the first hole H41 of the through hole H40, and the diameter of the semicircle is larger than the diameter of the handle member H55. As shown in FIG.

More specifically, the body member H53 and the pull-tab H55 are coupled through a screw connection. The pull-tab member H55 is slightly loosened, and the body member H53 and the pull- The fixing flange H553 is formed in a shape away from the outer surface of the first powder H1 so as to prevent interference with the movement of the moving member H50, The handle member H55 is naturally moved in the direction of the through hole H40 so that the fastening flange H553 and the fastening flange H553 are positioned at either one of the opposite ends of the first hole H41, Is inserted into the fixing groove H46 provided in the through hole H40 so that the movement of the moving member H50 can be prevented.

The fixing flange H553 is provided with a first magnet H555 and the second magnet H557 is provided on one side of the fixing groove H46 so that the fixing flange H553 is fixed to the fixing groove H46 of the first magnet H555 and the second magnet H557 are prevented from rotating arbitrarily by the magnetic forces of the first magnet H555 and the second magnet H557, the fixing force can be further improved. However, It should not be construed to limit the scope of rights.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various modifications, Modifications, alterations, and substitutions are to be construed as falling within the scope of protection of the present invention.

A: Pump assembly 10: Housing
11: upper body 111:
113: fourth flange portion 12: intermediate body
121: rising path 122: second flange portion
123: third flange portion 13:
131: Inflow path 133: First flange portion
135: extension part 15: fastening bolt
17: packing member 19: reinforcing member
20: pumping means 21:
211: rotation inducing member 23: wing group
25: wing member 251: water conveying path
252: first wing 253: second wing
254: third wing 255: fourth wing
27: connecting member 271: tooth connecting portion
30: drive means 31: drive motor
33: drive shaft

Claims (4)

A pumping means (20) including a rotating shaft (21) and a plurality of wing members (25) linearly coupled to the rotating shaft (21) to raise the water by rotation;
Driving means (30) comprising a driving motor (31) connected to the rotating shaft (21) and rotating the pumping means (20);
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When the pumping means 20 is rotated, water is raised along the wing members 25 by the rotation of the wing members 25,
The pumping means 20 and the driving means 30 are provided in the housing 10,
The housing (10)
A middle body 12 coupled to an upper portion of the lower main body 13 and water discharged from an upper portion of the intermediate body 12 to be lifted, And an upper main body 11 having a discharge path 111 formed therein
The intermediate body 12 is selectively coupled to one or more,
In the housing 10
A length adjusting means H composed of a first powder H1 and a second powder H2 inserted in the first powder H1 is provided to form the discharge path 111,
The length adjusting means (H)
A moving member H50 inserted in the through hole H40 and moving along the through hole H40; a second member H2, And a moving hole (H30) provided in the moving member (H50) to which the end of the moving member (H50) is coupled,
The moving hole H30 is formed such that the inclined portion H31 and the vertical portion H33 extending to the inclined portion H31 are repeated a plurality of times. Since the inclined portion H31 is formed in a zigzag shape, When the shifting member H50 moves along the through hole H40, the end of the shifting member H50 moves along the zigzag moving hole H30, so that the second powder H2 moves along the through- Is pulled out from the upper portion (H1) and adjusted in length. The method according to claim 1,
The lower body 13, the intermediate body 12, and the upper body 11 are each provided with pumping means 20,
Further comprising a connecting member (27) connecting the rotating shafts (21) of the respective pumping means (20) to each other. 3. The method according to claim 1 or 2,
A first flange portion 133 is formed on the lower main body 13,
A second flange portion 122 and a third flange portion 123 are formed on the intermediate body 12,
A fourth flange 113 is formed on the upper body 11,
The first flange 133 and the second flange 122 of the lower main body 13 and the intermediate main body 12 are coupled to each other,
Wherein the intermediate body (12) and the upper main body (11) are engaged with the third flange portion (123) and the fourth flange portion (113). The method of claim 3,
A packing member 17 is further provided between the first flange portion 133 and the second flange portion 122 and between the third flange portion 123 and the fourth flange portion 113 A vertical pump assembly for power generation.

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