KR102732651B1 - Driven agitator for water treatment with improved agitation efficiency - Google Patents

Abstract

The present invention relates to a water treatment driven agitator with improved stirring efficiency, and more specifically, to a water treatment driven agitator with improved stirring efficiency, which increases stirring efficiency through an air exhauster and agitator blades positioned underwater at the lower side while positioned on the water surface for water treatment by means of multiple buoyancy means.
The present invention for this purpose comprises a buoyancy body (10) provided with a buoyancy base plate (11) formed in the shape of a buoyant disc, and a buoyancy auxiliary plate (15) formed in the shape of a buoyancy disk with a diameter of 2/3 to 3/4 of the diameter of the buoyancy base plate (11) and spaced apart from the upper portion of the buoyancy base plate (11); a supply pipe (60) having a plurality of perforations (13) formed radially on the edge side of the buoyancy base plate (11) and connected to the center of the buoyancy auxiliary plate (15) and the buoyancy base plate (11) to supply and move air vertically downward; a protection pipe (30) that wraps and protects the outside of the supply pipe (60) that is extended to the lower side of the buoyancy base plate (11); A first buoyancy body (20) formed in an outwardly curved shape on the lower side of the buoyancy base plate (11), with a supply pipe (60) exposed from the lower end of the protective body (30); an upper end of the first buoyancy body (20) positioned so as not to interfere with the hole (13) formed in the buoyancy base plate (11), and an air exhauster (40) provided in a downwardly expanded shape on the lower end of the supply pipe (60); The air discharger (40) is formed in an upwardly curved shape, and a closing body (43) formed in an upwardly curved shape parallel to the inside is formed so that a passage (45) is formed between the supply discharger (40) and the closing body (43), a plurality of ventilation holes (41) are formed on the upper side of the upwardly curved supply discharger (40), air is discharged into water through the ventilation holes (41), and an agitating blade (50) is provided on the lower side of the air discharger (40) for water treatment; a horizontal finishing plate (52) is provided on the inner side of the finishing body (43) so that a space is formed between the horizontal finishing plate and the finishing body (43), a motor (53) is provided in the space, and the agitating blade (50) is provided at the end of a motor shaft (54) connected to the lower side of the motor (53).

Description

{Driven agitator for water treatment with improved agitation efficiency}

The present invention relates to a water treatment driven agitator with improved stirring efficiency, and more specifically, to a water treatment driven agitator with improved stirring efficiency, which increases stirring efficiency through an air exhauster and agitator blades positioned underwater at the lower side while positioned on the water surface for water treatment by means of multiple buoyancy means.

In general, sewage treatment plants are designed to treat sewage, wastewater, and sewage containing various pollutants, and treatment is performed using various methods such as physical, chemical, or biological methods.

In particular, the biological method is one of the widely applied methods because it is very useful for treating sewage containing organic pollutants by using microorganisms to remove pollutants. The method requires dissolved oxygen for the smooth operation of aerobic microorganisms, and additionally, mixing and stirring of the treated water are very important.

Therefore, a water treatment mixer is used to supply oxygen to wastewater and to stir and mix, and various types of mixers have been proposed.

For example, there is registered patent No. 10-0926000. The patent relates to a water treatment device and method, which comprises a magnetization-forming mixing tank equipped with a speed-controllable stirrer and a magnetic powder injection means and a coagulant injection means, and a magnetic stirrer treatment tank equipped with a speed-controllable magnetic stirrer, in a device for treating colloidal fine particle matter, microorganisms, and dissolved organic and inorganic substances in tap water or wastewater, wherein the device comprises: a magnetic stirrer treatment tank equipped with a speed-controllable magnetic stirrer, wherein when tap water or wastewater flows into the magnetic stirrer, the stirrer stirs the magnetic powder and coagulant, coagulating the fine particles in the tap water or wastewater to form magnetized flocs, and the magnetized flocs flow into the magnetic stirrer treatment tank stirred by the magnetic stirrer and attached to the magnetic stirrer to remove the fine particles in the tap water or wastewater. The device has a unique technical feature of removing the fine particles by using a magnetic substance.

Meanwhile, general agitators applied for water treatment have blades that simply rotate in the water and are combined with an air aeration device that supplies air through a separate device, so there was a problem that it was difficult to expect a high oxygen supply and a stirring effect on the treated water at the same time.

Registered Patent No. 10-0926000

Accordingly, the present invention was created to eliminate the above-mentioned problems, and the technical task of the present invention is to focus on a water treatment driven agitator with improved agitation efficiency that increases the agitation efficiency through an air discharger and agitation blades positioned underwater at the lower side while positioned on the water surface for water treatment by means of multiple buoyancy means.

In order to achieve the above technical task, the present invention comprises a buoyancy body (10) which comprises a buoyancy base plate (11) formed in the shape of a buoyant disc, and a buoyancy auxiliary plate (15) formed in the shape of a buoyancy disc with a diameter of 2/3 to 3/4 of the diameter of the buoyancy base plate (11) and spaced apart from the upper portion of the buoyancy base plate (11); a supply pipe (60) which has a plurality of holes (13) formed radially on the edge side of the buoyancy base plate (11) and is connected to the center of the buoyancy auxiliary plate (15) and the buoyancy base plate (11) to supply and move air vertically downward; a protection pipe (30) which wraps and protects the outside of the supply pipe (60) which is extended to the lower side of the buoyancy base plate (11); A first buoyancy body (20) formed in an outwardly curved shape on the lower side of the buoyancy base plate (11), with a supply pipe (60) exposed from the lower end of the protective body (30); an upper end of the first buoyancy body (20) positioned so as not to interfere with the hole (13) formed in the buoyancy base plate (11), and an air exhauster (40) provided in a downwardly expanded shape on the lower end of the supply pipe (60); The air discharger (40) is formed in an upwardly curved shape, and a closing body (43) formed in an upwardly curved shape parallel to the inside is formed so that a passage (45) is formed between the supply discharger (40) and the closing body (43), a plurality of ventilation holes (41) are formed on the upper side of the upwardly curved supply discharger (40), air is discharged into water through the ventilation holes (41), and an agitating blade (50) is provided on the lower side of the air discharger (40) for water treatment; a horizontal finishing plate (52) is provided on the inner side of the finishing body (43) so that a space is formed between the horizontal finishing plate and the finishing body (43), a motor (53) is provided in the space, and the agitating blade (50) is provided at the end of a motor shaft (54) connected to the lower side of the motor (53).

In addition, a second buoyancy body (25) is provided on the surface of a supply pipe (60) positioned between the buoyancy assistance plate (15) and the buoyancy base plate (11), and the upper and lower surfaces of the second buoyancy body (25) are configured to be in close contact with the lower surface of the buoyancy assistance plate (15) and the upper surface of the buoyancy base plate (11).

In addition, a grooved portion (23) is formed on the surface (21) of the first buoyancy body (20), and the grooved portion (23) is composed of a horizontal portion (23a) parallel to the water surface (2) and an inclined portion (23b) formed to be inclined outward from the inner end of the horizontal portion (23a), thereby allowing treatment water to flow into the grooved portion (23), thereby increasing the buoyancy effect of the first buoyancy body (20).

In addition, the invention is characterized in that a plurality of protrusions (62) are provided in a horizontal, belt-like shape at regular intervals on the inner surface of the lower side of the supply pipe (60) so that the air supplied through the supply pipe (60) increases in speed as it passes through the plurality of protrusions (62).

In addition, it is characterized in that a dispersing protrusion (71) having a pointed tip is formed on the upper part of the closing body (43) located on the lower side of the supply pipe (60) to facilitate the diffusion and movement of air.

According to the present invention described above, there is an effect such as increasing the mixing efficiency through an air exhauster and a stirring blade positioned underwater on the lower side while positioned on the water surface for water treatment by means of multiple buoyancy means.

Figure 1 is a perspective view of a water treatment drive stirrer with improved stirring efficiency according to the present invention.
Figure 2 is an example cross-sectional view of Figure 1.
Figure 3 is an example of a state of use according to the present invention.
Figures 4 and 5 are examples of modified embodiments according to the present invention.

Hereinafter, specific details for implementing the present invention will be described in more detail with reference to the attached drawings.

The present invention relates to a water treatment driven agitator with improved stirring efficiency, and more specifically, to a water treatment driven agitator with improved stirring efficiency, which increases stirring efficiency through an air exhauster and agitator blades positioned underwater at the lower side while positioned on the water surface for water treatment by means of multiple buoyancy means.

In the configuration of the present invention, a buoyancy body (10) positioned on the water surface (2) by buoyancy is provided for water treatment of treated water as shown in FIGS. 1 and 3.

The above buoyancy body (10) is provided in multiples of at least two, and as an example, a buoyancy base plate (11) formed in a circular shape having buoyancy as shown in FIGS. 1 and 2 is provided, and a buoyancy auxiliary plate (15) formed in a circular shape having buoyancy with a diameter of 2/3 to 3/4 of the diameter of the buoyancy base plate (11) is provided, spaced apart from the upper portion of the buoyancy base plate (11).

The above buoyancy base plate (11) is positioned on the water surface (2), and the buoyancy auxiliary plate (15) is used to maintain the buoyancy effect when the treatment water increases rapidly.

At this time, a number of holes (13) are formed on the edge side of the buoyancy base plate (11), and the buoyancy is increased by allowing the outside air and the treated water to rub against the holes (13). In addition, at this time, as shown in Fig. 4, if the holes (13) are formed in a downwardly expanding form to form an inclined portion (14), the buoyancy effect by the holes (13) is maximized because the treated water rubs against the inclined portion (14).

Meanwhile, as shown in FIGS. 1 and 2, a supply pipe (60) is provided that is connected to the center of the buoyancy auxiliary plate (15) and the buoyancy base plate (11) to supply and move air vertically downward, and a protection pipe (30) is provided that wraps around and protects the outside of the supply pipe (60) that is extended to the lower side of the buoyancy base plate (11).

At this time, the supply pipe (60) is configured to be exposed from the lower part of the protective pipe (30) to the lower outer side.

And, a first buoyancy body (20) formed in an outwardly curved shape is provided on the lower side of the buoyancy base plate (11). The buoyancy body (20) is formed of a buoyancy material having buoyancy, and in order to increase the buoyancy effect, the surface (21) is formed in an outwardly curved shape as shown in Fig. 3, and also, the upper part of the first buoyancy body (20) is configured so as not to interfere with the hole (13) formed in the buoyancy base plate (11).

At this time, as a modified embodiment, a groove (23) is formed on the surface (21) of the first buoyancy body (20) as shown in Fig. 4, and the groove (23) is configured to include a horizontal portion (23a) parallel to the water surface (2) and an inclined portion (23b) formed to be inclined outward from the inner end of the horizontal portion (23a), thereby allowing treatment water to flow into the groove (23), thereby increasing the buoyancy effect of the first buoyancy body (20).

In addition, as a modified embodiment, a second buoyancy body (25) is provided on the surface of the supply pipe (60) located between the buoyancy auxiliary plate (15) and the buoyancy base plate (11) as shown in Fig. 4, and the upper and lower surfaces of the second buoyancy body (25) are configured to be in close contact with the lower surface of the buoyancy auxiliary plate (15) and the upper surface of the buoyancy base plate (11).

At this time, if a vertical partition (16) in the shape of a circular tube is provided between the buoyancy auxiliary plate (15) and the buoyancy base plate (11) and spaced apart from the outside of the second buoyancy body (25), and a sealed space (17) is formed between the vertical partition (16) and the second buoyancy body (25), the buoyancy effect is further increased.

Meanwhile, as shown in FIGS. 1 and 2, an air exhauster (40) is provided in a downward expansion form at the lower end of the supply pipe (60).

As shown in FIGS. 2 and 3, the air discharger (40) is formed in an upwardly curved shape, and a closing body (43) formed in an upwardly curved shape parallel to the inside is formed so that a passage (45) is formed between the supply discharger (40) and the closing body (43), and a plurality of ventilation holes (41) are formed on the upper side of the upwardly curved supply discharger (40), so that air is discharged into the water through the ventilation holes (41).

The above air exhauster (40) is connected to the lower end of the supply pipe (60) located on the upper side, and as a modified embodiment of the present invention, as shown in FIG. 5, a plurality of protrusions (62) are provided in a horizontally circular band shape at regular intervals on the inner surface of the lower side of the supply pipe (60) so that the air supplied through the supply pipe (60) increases in speed as it passes through the plurality of protrusions (62).

In addition, a dispersing projection (71) with a pointed tip is formed on the upper part of the closing body (43) located at the lower side of the supply pipe (60) to facilitate the diffusion and movement of air.

Meanwhile, as shown in FIGS. 1 and 2, a stirring blade (50) is provided on the lower side of the air exhauster (40) for water treatment.

Referring to Fig. 2, a horizontal finishing plate (52) is provided on the inner side of the finishing body (43) so that a space is formed between the horizontal finishing plate and the finishing body (43), a motor (53) is provided in the space, and a stirring blade (50) is provided at the end of a motor shaft (54) connected to the lower side of the motor (53).

The above-mentioned stirring blade (50) is rotated by a motor (53) to stir the treatment water, and the stirred treatment water rises and rubs against the air supplied to the treatment water through the air exhauster (40), thereby effectively performing water treatment.

At this time, the stirring blades (50) may be provided in multiple pieces spaced apart from each other as shown in FIG. 5, and if the rotation radius of the stirring blades (50) becomes smaller from the lower side to the upper side, the transmission of rotational pressure to the air exhauster (40) from the upper side is minimized, while the maximum rotational force can be generated from the lower side.

According to the water treatment drive agitator with improved mixing efficiency of the present invention described above, the mixing efficiency can be increased through the air exhauster and the mixing blades located in the lower part of the water while positioned on the water surface for water treatment by multiple buoyancy means.

The present invention described above has been described with reference to an embodiment shown in the drawings, but this is merely exemplary, and it should be made clear that various modifications and equivalent other embodiments are possible from this by those skilled in the art. Therefore, the true technical protection scope of the present invention should be interpreted by the appended claims, and all technical ideas within a scope equivalent thereto should be interpreted as being included in the scope of the rights of the present invention.

10: Buoyancy body 11: Buoyancy base plate
15: Buoyancy plate 20: First buoyancy body
30: Protective body 40: Air exhauster
41: Perforation 43: Closure
45: Aisle 50: Stirrer
60: Supply pipe

Claims (5)

In constructing a driving agitator for water treatment,
A buoyancy body (10) provided with a buoyancy base plate (11) formed in a buoyant disc shape and a buoyancy auxiliary plate (15) formed in a buoyant disc shape with a diameter of 2/3 to 3/4 of the diameter of the buoyancy base plate (11) spaced apart from the upper portion of the buoyancy base plate (11); a plurality of perforations (13) are formed radially on the edge side of the buoyancy base plate (11),
A supply pipe (60) that is connected to the center of the buoyancy auxiliary plate (15) and the buoyancy base plate (11) and supplies and moves air vertically downward;
A protective tube (30) that wraps and protects the outside of a supply tube (60) that is extended to the lower side of the buoyancy base plate (11); a supply tube (60) is exposed from the lower end of the protective tube (30) to the lower outer side,
A first buoyancy body (20) formed in an outwardly curved shape on the lower side of the buoyancy base plate (11); the upper part of the first buoyancy body (20) is positioned so as not to interfere with the hole (13) formed in the buoyancy base plate (11);
An air discharger (40) provided in a downwardly expanded form at the lower end of the supply pipe (60); the air discharger (40) is formed in an upwardly curved form, and a closing body (43) formed in an upwardly curved form parallel to the inside is formed, so that a passage (45) is formed between the supply discharger (40) and the closing body (43), and a plurality of ventilation holes (41) are formed on the upper side of the upwardly curved supply discharger (40), so that air is discharged into the water through the ventilation holes (41).
A water treatment driven agitator with improved agitation efficiency, characterized in that: an agitating blade (50) is provided for water treatment on the lower side of the air exhauster (40); a horizontal finishing plate (52) is provided on the inner side of the finishing body (43) so that a space is formed between the horizontal finishing plate and the finishing body (43), a motor (53) is provided in the space, and an agitating blade (50) is provided at the end of a motor shaft (54) connected to the lower side of the motor (53).
In the first paragraph,
A water treatment drive agitator with improved stirring efficiency, characterized in that a second buoyancy body (25) is provided on the surface of a supply pipe (60) positioned between the buoyancy auxiliary plate (15) and the buoyancy base plate (11), and the upper and lower surfaces of the second buoyancy body (25) are configured to be in close contact with the lower surface of the buoyancy auxiliary plate (15) and the upper surface of the buoyancy base plate (11).
In the second paragraph,
A water treatment drive agitator with improved stirring efficiency characterized in that a grooved portion (23) is formed on the surface (21) of the first buoyancy body (20), the grooved portion (23) is composed of a horizontal portion (23a) parallel to the water surface (2) and an inclined portion (23b) formed to be inclined outward from the inner end of the horizontal portion (23a), thereby allowing treatment water to flow into the grooved portion (23), thereby increasing the buoyancy effect of the first buoyancy body (20).
In the third paragraph,
A water treatment driven agitator with improved agitation efficiency, characterized in that a plurality of protrusions (62) are provided in a horizontal, belt-like shape at regular intervals on the inner surface of the lower side of the supply pipe (60) so that air supplied through the supply pipe (60) increases in speed as it passes through the plurality of protrusions (62).
In paragraph 4,
A water treatment driven agitator with improved agitation efficiency, characterized in that a dispersion projection (71) with a pointed tip is formed on the upper portion of a closing body (43) located at the lower end of the supply pipe (60) to facilitate the diffusion and movement of air.

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