KR100907246B1 - A separable impeller - Google Patents

Abstract

A separable impeller is provided to improve contact with the air of wastewater, and to improve the amount of dissolved oxygen of the wastewater by combining simply a plurality of guide wings with an outer circumference of an impeller wing. A separable impeller includes a circular impeller wing, an agitating wing, and a plate-shaped rectangular guide wing(30). The impeller wing is combined with a rotating shaft or an extension shaft of a motor. The agitating wing is protruded on a lower part of the impeller wing at a constant angle. The plate-shaped rectangular guide wing is combined with an outermost part of the impeller wing at a constant distance. Each fastening unit(50) of the impeller wing and the guide wing includes a plurality of hinge pieces(51), a corresponding hinge(52), and a hinge shaft(55). A screw(57) is formed on sides of the hinge shaft, and the screw is combined with a screw bolt(58). A pressurization protrusion(71) is formed on a screw bolt head(59).

Description

Removable Impellers {A SEPARABLE IMPELLER}

The present invention relates to a separate type impeller of the aeration tank used in the waste water purification facility. In particular, by forming a separate impeller, a circular impeller wing at the outermost part of the round connecting plate-shaped guide wings at regular intervals, when the impeller rotates the guide wing also rotates downward force generated from the guide wing It is a separate impeller that improves the amount of dissolved oxygen in the wastewater by improving the contact with the air by the waves and improves the contact with the air, and converts the rising vortex which is a problem of the circular impeller wing.

In general, in the wastewater purification treatment plant, it is essential to increase the amount of dissolved oxygen by contacting the wastewater and air in the aeration tank. That is, in the case of waste water, a number of processes are required to improve its water quality. In particular, the aeration tank induces contact between the waste water and air to improve dissolved oxygen in the waste water and promotes digestion by aerobic bacteria. Will go through. At this time, the process of increasing the dissolved oxygen of the waste water in the aeration tank has been proceeded in two conventional methods.

One is to increase the dissolved oxygen inside the waste water by continuously supplying oxygen to the waste water through a brow or a fan, and the other is a contact surface with air by rotating a large amount in the state in which the waste water is brought into contact with air. This is how you increase it.

The present invention corresponds to a separate type of impeller used in the method of stirring and rotating the latter wastewater of the conventional method of improving the dissolved oxygen amount.

That is, as shown in FIG. 1, the conventional detachable impeller 100 is coupled to a separate reducer 81 at the end of the motor 1, and forms a rotation shaft 2 extending from the shaft. Of course, when a separate coupling 83 is required to further extend the above-described rotation shaft 2, another extension shaft 82 is fixed using the coupling 83, and the extension shaft 82 is The impeller 100 is fastened to the end.

At this time, the impeller 100 is formed with an impeller wing 10 having a large diameter of a circular axial hole is fixed to the shaft, the stirring wing is formed to protrude at a predetermined angle to the lower end of the impeller wing 10 20 is fastened. Therefore, the impeller 100 is introduced into the aeration tank 84 for storing the waste water to agitate the waste water 85.

At this time, the impeller 100 is to submerge the impeller 100 to a certain level, that is, slightly entered from the water level surface of the waste water 85, as shown in FIG. The upper part of the impeller wing 10 of the impeller 100 is to start the rotation in a state to be slightly locked in the water surface. Then, as the impeller wing 10 rotates, the plurality of stirring wings 20 fastened to the impeller wing 10 also rotate, and the waste water 85 is agitated and the contact surface with air is enlarged.

However, such a conventional impeller 100 has the following problems.

First, when the impeller wing 10 is rotated, it is practically hard to cause a wave to the entire outer portion of the aeration tank 84. Therefore, dissolved oxygen cannot be rapidly increased. The diameter of the aeration tank 84 is wide and the diameter of the impeller wing 10 penetrating to the upper portion is narrow but the water acting on the impeller wing 10 and the stirring wing 20 causes centrifugal force to the outside of the impeller wing 10. It does not stretch out and changes to a wave rising upward as shown in FIG.

This is a problem that occurs due to the magnetic levitation of the waste water 85 because there was no configuration that generates an outward force at the end of the impeller wing (10).

Second, in order to improve the dissolved oxygen content of the waste water in the aeration tank 84 by using the impeller 100, a plurality of impellers 100 must be introduced into the aeration tank 84 and stirred. This creates a problem that is expensive and cumbersome in performing aeration.

The present invention relates to a separate type impeller of the aeration tank used in the wastewater purification facility, to form a separate type impeller, connecting the rounded plate-shaped guide wings at regular intervals at the outermost part of the circular impeller wing, during the rotation of the impeller The guide wing rotates as well, and the wave spreads throughout the aeration tank by the downward force generated from the guide wing to improve contact with air, and converts the rising vortex, which was a problem of the circular impeller wing, into a vortex that downwards. It is intended to provide a separate impeller that improves the amount of dissolved oxygen.

Separable impeller according to the present invention is a separate impeller used in the aeration tank of the waste water purification facility, the circular impeller wing 10 coupled to the rotation shaft (2) or the extension shaft (82) of the motor (1); Stirring wing 20 for protruding at a predetermined angle to the lower end of the impeller wing (10); And a quadrilateral guide wing 30 on a plate circumferentially rounded in a concave shape at the outermost portion of the circular impeller wing 20 at regular intervals, and concave therein. When the impeller (10) rotates by), the guide wing (30) at the end is rotated to extend the rotation of the wave as a whole and is configured to include a wave in the downward direction of the water surface.

In addition, according to the present invention, the impeller wing 10, the fastening means 50 of the impeller wing 10 and the guide wing 30, each of the two at a constant interval from the outermost part of the impeller wing 10 at a lower end thereof. Protruding hinge pieces 51; A corresponding hinge 52 protruding at a predetermined interval on the upper surface of each of the guide wings 30 to correspond to the hinge piece 51; And a hinge shaft 55 inserted into the hinge holes 53 and 54 of the hinge piece 51 and the corresponding hinge 52, and is coupled to the guide wing 30 rounded at the outermost part of the impeller 10. To adjust the angle by the rotation of the hinge shaft 55: In the hinge shaft 55, screws 57 are formed on both left and right ends of empty spaces inside the hinge shaft 55, and the screw ( Fastening the screw bolt 58 to 57, forming a protruding pressing protrusion 71 in the head 59 of the screw bolt 58 to control the guide angle of the guide wing 30; The fastening means 50, the through hole 209 penetrates from side to side at the end of the stirring ring 20; An insertion hole 210 in which a central portion of the guide wing 30 is cut to be inserted in a direction perpendicular to the stirring ring 20, and a hinge 52 protruding from both left and right ends to an upper portion of the insertion hole 210; A hinge hole 201 therein; And a fastening bolt 202 penetrating through the hinge hole 201 of the hinge 52 and penetrating the through hole 209 of the stirring wing 20 fitted into the insertion hole 210 of the guide wing 30. A nut 203 corresponding thereto is included.

According to the present invention, by combining the guide wing to the outside of the impeller wing very simply by changing the wave generated inside the aeration tank to a larger and wider wave has the advantage that the dissolved oxygen in the waste water can be improved exponentially.

In addition, according to the present invention, it is possible to fasten the guide wing in a simple manner to the impeller wing of the conventional impeller has the advantage of high availability.

In addition, according to the present invention, the guide wing coupled to the impeller wing is capable of controlling the change in the angle while the method of coupling may maintain a constant angle is an advantage that can control the water generated in the waste water have.

In addition, according to the present invention, it is applied to aeration tanks of various sizes by adjusting the coupling angle of the guide wing has the advantage that the installation cost is low because it improves the workability to cause the aeration tank as a whole.

The present invention relates to a separate type impeller used in the aeration tank of the waste water purification facility. Therefore, the configuration of the present invention and its operation will be described in detail with reference to FIGS. 2 to 5.

As shown, the present invention has a circular impeller wing 10 coupled to the rotational shaft 2 or the extension shaft 82 of the motor 1, and protrudes at a predetermined angle to the lower end of the impeller wing 10 There is a stirring wing 20 to be formed, and fastened in the form of a central point symmetrical at regular intervals at the outermost part of the circular impeller wing 20, the four-sided guide wing 30 on the plate concave round inwardly There is this. Therefore, when these are combined, the impeller 10 is rotated by the motor 1, and the guide wing 30 at the end is rotated to expand the rotation of the wave throughout the aeration tank and cause the wave downward in the water surface.

Prior to the description of the present invention, the description of the present invention will be made clearer by explaining the "aeration" and "aeration tank" of the wastewater purification treatment facility in which the impeller 100 of the present invention is used.

Aeration is a term used in sewage treatment and is an operation in which water and air are sufficiently brought into contact with each other by blowing air into the water or spraying water into the air (increased dissolved oxygen). Through this manipulation, it promotes oxidation and digestion by aerobic bacteria. In addition, if the dissolved oxygen is increased in the waste water, microorganisms may be introduced. That is, this microorganism removes carbon dioxide, hydrogen sulfide, methane gas, etc. by the digestion action. In other words, aeration in wastewater and wastewater causes microorganisms to purify water.

Next, the aeration tank is the main equipment of the activated sludge method, and there are air suction type, mechanical stirring type, and quantum combination type. The effective volume of the aeration tank is determined by the quality and quantity of the wastewater to be treated and the operating conditions. After all, aeration tank refers to a tank prepared for aeration as described.

The present invention will now be described. The present invention may be manufactured in the form of fastening the guide wing 30 to the detachable impeller 100 is generally used. That is, as shown, the guide wing 30 shown in a rounded concave shape is coupled to the outer portion of the impeller wing 10 fastened to the extension shaft 82 of the motor 1 is coupled. As shown in Figure 2 is to fasten the guide wing 30 is a concave shape of the lower part.

The guide wings 30 are provided in plural, and are fastened at a predetermined distance from the center point of the impeller wing 10, and are preferably fastened to extend outwardly from the impeller wing 10. Therefore, when the motor 1 rotates, the extension shaft 82 connected to the shaft of the motor 1 rotates, and the impeller wing 10 coupled to the end of the extension shaft 82 rotates. . In addition, the stirring wing 20 protruding in the vertical direction is fastened to the lower end of the impeller wing 10 to rotate the waste water 85 in the aeration tank 84. And this rotational force is to promote the friction with the air in contact while changing the position of the top and bottom of the waste water (85). This action allows a large amount of oxygen to be contained in the waste water because the friction area, that is, the contact area between the air and the waste water is enlarged.

By the way, in the present invention, the guide wing 30 extending further to the impeller wing 10 is in a fastened state. Therefore, the guide wing 30 forms a wider range of vortices in the waste water 85 at the bottom while rotating with the rotation of the impeller wing 10.

That is, as shown in Figure 3, a somewhat concave guide wing 30 is rotated, and generates a vortex in the waste water 85 of a larger area, while generating a vortex that extends downward to the outer portion. It is to take full advantage of the centrifugal force generated in the guide wing (30). Conventional impeller 100 is such that there is no guide wing 30, as shown in Figure 1, the outermost portion of the impeller wing 30, the vortex that rises to the top rather than the downward vortex generated downward vortex aeration tank ( 84) It did not spread to the whole area of the area, and the downward force was weak so that the action of overturning the waste water 85 of the upper and lower portions was not active. However, the present invention completely solves this problem by fastening the illustrated guide wing 30 to the impeller wing 10.

By the way, in the present invention, in the fastening the guide wing 30 to the impeller wing 10, it is possible to fasten while allowing to adjust the guide angle of the impeller wing (10). That is, the fastening means 50 of the impeller wing 10 and the guide wing 30, the hinge pieces 51 which protrude in two each at regular intervals from the outermost part of the impeller wing 10 to the lower end thereof. ) And a corresponding hinge 52 which protrudes at a predetermined interval on the upper surface of each of the guide wings 30 to correspond to the hinge piece 51, and the hinge piece 51 and the corresponding hinge 52. There is a hinge shaft 55 to be fitted to the hinge holes (53, 54). Therefore, these are combined to adjust the angle of the rounded guide wing 30 in the outermost of the impeller (10) by the rotation of the hinge shaft (55).

In fastening the above-mentioned guide wing 30, hinge coupling is achieved. A hinge piece 51 protruding downward is formed at the outermost part of the impeller wing 10, and a corresponding hinge 52 corresponding to the hinge piece 51 is formed on the guide wing 10. , End of the guide 30, that is, the guide wing 30 is to protrude to the top of one end that can be connected to the impeller wing (10). Then, the hinge piece 51 and the hinge shaft 55 of the circular cross section shown in the corresponding hinge 52 are fitted. Then, when the operator exerts a pressing force, the guide wing 30 may be caught at an appropriate angle while the guide wing 30 is twisted in the left and right direction about the hinge shaft 55.

The reason for this action is that the impeller 100 can be installed in aeration tank 84 of a wide variety of sizes. At this time, by appropriately adjusting the guide angle of the guide wing 30 will be able to cause the entire wave inside the aeration tank (84). That is, in a wider aeration tank 84, the wave spreads farther in a manner of lifting the head so that the hinge shaft 55 can approach the water level of the wastewater 85 to the other side of the guide wing 30 coupled thereto. Induce. However, in the small diameter aeration tank, the tip of the guide wing 30 is lowered, so that the direction of the wave is more weighted downward. As a result, by adjusting the guide angle of the guide wing 30 of the present invention, the impeller 100 of the present invention is to be able to use in more various workplaces.

In the present invention, the hinge shaft 55, the screw 57 is formed on both left and right ends of the empty space inside the hinge shaft 55, the screw bolt 58 is fastened to the screw 57, The head 59 of the screw bolt 58 forms a protruding pressing protrusion 71 to control the guide angle of the guide wing 30. In other words, once the guide angle of the guide wing is adjusted so that the guide angle is always maintained.

To this end, in the present invention, the screw shaft 58 is fastened to the screws 57 at both ends of the hinge shaft 55 in a state where the hinge shaft 55 is fitted to the hinge piece 51 and the corresponding hinge 52. . By the way, the screw bolt 58 is formed with a plurality of protruding pressing protrusions 71 in the head. That is, as the screw bolt 58 is screwed into the through hole of the hinge shaft 55 and enters the inside, the screw bolt 58 is in a state of pressing the corresponding hinge 52 of the guide wing 30. At this time, the hinge piece 51 of the impeller wing 10 and the corresponding hinge 52 of the guide wing 30 are placed in close overlap with each other, and the screw bolt (left and right ends at both ends of the hinge shaft 55 sandwiched therein). As the 58 is inserted, the pressing protrusion 71 protruding from the head serves to bring the corresponding hinge 52 of the guide wing 30 into close contact with the hinge piece 51. As a result, a large frictional force is applied to the hinge piece 51, the corresponding hinge 52, and the head pressing protrusion 71 of the screw bolt 58, so that the screw bolt 58 is not released. Guide angle can not be adjusted.

Therefore, the guide wing 30 of the present invention, after the operator adjusts the proper angle in accordance with the working environment, and pulls up the friction force to the screw bolt (58) to the maximum, the operation without changing the guide angle by the vibration according to the rotation It can be done.

And, if attached to the description, in the case of the present invention as shown in Figure 6, proposes another embodiment of the fastening means for fastening the guide wing. That is, the fastening means 50 has a through hole 209 penetrating left and right at the end of the stirring ring 20, the guide wing 30 to be inserted in a direction perpendicular to the stirring ring 20. Insertion hole 210 cut in the center of the, there is a hinge 52 and a hinge hole 201 inside the protrusion 52 formed to protrude on both left and right ends of the insertion hole 210, the hinge hole of the hinge 52 There is a fastening bolt 202 and a corresponding nut 203 passing through the 201 and penetrating the through hole 209 of the stirring wing 20 fitted into the insertion hole 210 of the guide wing 30. .

The guide wing 30 is fastened to the stirring wing 20. Through holes 209 are formed in the stirring wing 20, and the guide wing 30 is inserted into the stirring wing 20. At this time, the insertion hole 210 is formed by cutting the center of the guide wing 30 to enable the fitting thereof. Therefore, the insertion hole 210 is coupled to each other by fitting the ends of the stirring wing 20. Of course, in order to further secure this coupling, the fastening bolt 202 is inserted into the hinge 52, and penetrates the through hole 209 of the stirring wing 20 inserted into the insertion hole 210, again. The end of the fastening bolt 202 is to pass through the other hinge 52, the hinge hole 201 of the guide wing (30). Of course, the fastening bolts 202 are fastened firmly through the nut 203 so as not to fall out from each other.

Then, the fastening angle of the guide wing 30 is appropriately adjusted, and the nut 203 is tightened strongly to complete the fastening.

1 is a view showing a state of forming a vortex in the waste water through the conventional common detachable impeller,

2 is a view showing a state of forming a vortex in the waste water through the separate impeller according to the present invention,

3 is a view showing a plane and a cross section of the impeller according to the present invention,

Figure 4 is an exploded perspective view showing a guide wing fastening structure of the present invention,

Figure 5 is an enlarged cross-sectional view showing a fastening structure of the present invention.

6 is an exploded perspective view showing another embodiment of the fastening structure of the present invention.

<Brief description of the major symbols in the drawing shown>

One; Motor 2; Pivot

10; Impeller wing 20; Stirring wing

30; Guide wing 50; Fastening means

51; Hinge piece 52; Corresponding hinge

55; Hinge axis 57; screw

58; Screw bolt 71; Pressurized protrusion

81; Reducer 82; Extension shaft

83; Coupling 84; Aeration tank

85; Waste water 100; Impeller

Claims (3)

delete A circular impeller wing 10 coupled to the rotation shaft 2 or the extension shaft 82 of the motor 1; Stirring wing 20 for protruding at a predetermined angle to the lower end of the impeller wing (10); And Fastened to the outermost portion of the circular impeller wing 20 in the form of a central point symmetrical at regular intervals, a concave round four-way guide wing 30 on the plate; is coupled, the motor (1) When the impeller (10) rotates by, the guide wing (30) at the end of the rotation of the split type impeller extending the rotation of the wave as a whole aeration tank and causing the wave in the downward direction of the water surface, The fastening means 50 of the impeller wing 10 and the guide wing 30, Hinge pieces 51 each protruding from the outermost portion of the impeller wing 10 at regular intervals from each other at two ends; A corresponding hinge 52 protruding at a predetermined interval on the upper surface of each of the guide wings 30 to correspond to the hinge piece 51; And Hinge shaft (55) to be fitted to the hinge hole (51, 54) of the hinge piece 51 and the corresponding hinge (52); is coupled to round the guide wing 30 in the outermost of the impeller (10) Hinge shaft 55; and In the hinge shaft 55, The screw 57 is formed on both left and right ends of the empty space inside the hinge shaft 55, The screw bolt (58) is fastened to the screw (57), and the head (59) of the screw bolt (58) forms a protruding pressing protrusion (71) to adjust the angle by the rotation of the guide wing (30). Detachable impeller characterized in that. The method according to claim 2, The fastening means 50, Through holes 209 penetrating from side to side at the end of the stirring ring 20; An insertion hole 210 in which a central portion of the guide wing 30 is cut to be inserted in a direction perpendicular to the stirring ring 20, and a hinge 52 protruding from both left and right ends to an upper portion of the insertion hole 210; A hinge hole 201 therein; And Fastening bolt 202 penetrating through the hinge hole 201 of the hinge 52, and penetrating the through hole 209 of the stirring wing 20 fitted into the insertion hole 210 of the guide wing 30 and Removable impeller comprising a corresponding nut (203).

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