KR101200034B1 - Multi-function Agitator - Google Patents

Abstract

PURPOSE: A multi-functional agitator is provided to improve agitating efficiency by uniformly agitating whole objects stored in a tank. CONSTITUTION: A multi-functional agitator comprises a motor(30), a driving shaft(20) and an impeller. The impeller comprises a main hub(110), a sub hub(120), an extended tube(130), and multiple main blades(140). The main hub is rotated by being connected with a driving shaft and has a cone shape which has a diameter which gradually gets bigger away from the driving shaft. The sub hub surrounds the main hub by being spaced from the main hub. The sub hub is rotated with the main hub and has the diameter which becomes bigger from the upper end to the lower end. An extension pipe is installed at the top end of the sub hub. The extension pipe surrounds the driving shaft by being spaced from the driving shaft.

Description

Multi-function Agitator

The present invention relates to an agitator, and in particular, an auxiliary hub which surrounds the main hub at a predetermined interval outside the main hub formed of a cone type is disposed, and an impeller comprising a plurality of blades formed between the main hub and the auxiliary hub. The present invention relates to a multifunctional stirrer provided to effectively stir a wide range of stirring objects.

In general, a stirrer is a device for stirring and mixing a liquid and a liquid, a liquid and a solid, or powder. The stirrer may be classified into a tank stirrer and a fluid stirrer according to a stirring type, and a tank stirrer is mainly used.

The tank stirrer is to put a stirring object and a stirring device in the tank, it can be divided into propeller type, orr type, turbine type, spiral shaft type and the like according to the type of stirring blade. In this case, the propeller type is used for stirring liquids having low viscosity or liquids containing solid particles, the OR type is used for low viscosity, and has a simple structure. The turbine type uses centrifugal force and has high stirring efficiency. It has a characteristic, The said spiral-shaft type | mold has the characteristic which the effective stirring of a high viscosity stirring material is possible.

As the conventional stirrer is a swirl flow is formed by the rotation of the impeller installed to be immersed in the stirring object, a collision between the stirring objects is generated in the course of the flow of the stirring object along the swirl flow formed as described above to make the stirring of the stirring object You lose.

However, in the conventional impeller, the flow of the stirring object generated by the rotation of the impeller has a constant flow in the horizontal direction or the vertical direction, and the flow of the stirring object having the constant flow is reflected while colliding with the wall surface of the tank, thereby Since the circulating swirl flow is formed, there is a problem that the stirring is effectively performed only around the impeller.

In this case, the impeller is configured in multiple stages so that even agitation may be performed in the tank, but in this case, the structure is complicated and the installation cost increases, and power consumption also has a big disadvantage.

Meanwhile, Korean Patent No. 0921011 discloses a deep stirrer using an impeller having a conical structure.

1 shows a front view of a deep stirrer disclosed in Korean Patent No. 0921011.

The impeller 10 provided in the deep stirrer is composed of a structure in which a plurality of stirring wings 11 protruding in the form of screws at regular intervals on the outer inclined surface of the conical body.

The conical impeller as described above is installed so as to be close to the bottom of the tank, the rotation of the impeller installed close to the bottom is formed while a swirl flow circulating through the tank is made to stir the stirring object.

However, the conical impeller as described above also has a problem that it is difficult to effectively stir the stirring object located on the top of the tank due to the nature of forming a swirl flow by locally flowing the stirring object located on the bottom of the tank.

In addition, the stirrer used in the waste water purification facility is generally used in combination with an air injection device that injects oxygen into the waste water to induce effective purification of the waste water, but the structure of the facility is complicated by using a separate air injection device. And equipment costs also increase, power consumption also has a big problem.

The present invention has been made in consideration of the above problems, an object of the present invention is accelerated by the centrifugal force in the course of the stirring object flows through the flow path formed in the impeller is ejected at a high pressure from the impeller, and also of the flow path The inlet and the outlet are formed so as to be spaced apart from the upper and lower portions of the stirring object to provide a multifunctional stirrer capable of effectively stirring a wide range of the stirring object.

Another object of the present invention is to provide a multifunctional stirrer that can inject oxygen into the stirring object through the rotation of the impeller without a separate air injection device, simplifying the structure of the equipment, and reducing the equipment cost and power consumption. .

The multifunctional stirrer of the present invention, which achieves the object as described above and accomplishes a problem for eliminating the conventional drawback, comprises a motor, a drive shaft extending from the motor and rotating by driving of the motor, and an impeller installed on the drive shaft. In the stirrer, the impeller is connected to the drive shaft, the main hub is formed of a cone type having a diameter that extends away from the drive shaft; It is arranged to surround the main hub spaced apart from the main hub to form a flow path for the flow of fluid between the main hub, combined with the main hub and rotates with the main hub, from the upper end to the lower end An auxiliary hub formed of a cone type having an expanded diameter; An extension tube installed at an upper end of the auxiliary hub and having a structure surrounding the drive shaft while being spaced apart from the drive shaft at a predetermined interval, and extending along the drive shaft to extend the flow path to an upper layer of the stirring object; And a plurality of main blades formed to protrude in a spiral shape on the outer surface of the main hub to introduce fluid through the upper end of the flow path and discharge the fluid through the lower end of the flow path when the main hub rotates. .

The main hub and the auxiliary hub may be coupled to each other via a main blade.

Meanwhile, the impeller may further include a plurality of auxiliary blades spirally protruding from the outer surface of the auxiliary hub to generate another swirl flow with the main blade.

In this case, the auxiliary blade may be formed as a main blade formed in the main hub protrudes through the auxiliary hub to be integral with the main hub.

On the other hand, the upper end of the main hub may be further formed with a plurality of inlet holes for introducing the stirring object located in the lower portion of the impeller into the flow path.

In addition, in the present invention, the extension pipe of the impeller is formed to protrude to the outside of the stirring object is configured so that the outside air flows into the flow path between the main hub and the auxiliary hub, the outer surface of the auxiliary hub is formed to protrude in a spiral It may be configured that a plurality of auxiliary blades for flowing the stirring object during the rotation of.

At this time, the main hub and the auxiliary hub is formed with a plurality of air discharge holes through which the air flowing through the flow path is discharged.

According to the present invention having the above characteristics, the stirring object flowing through the upper end of the flow path formed between the main hub and the auxiliary hub during the rotation of the impeller is accelerated by the main blade and then high pressure through the lower end of the flow path In this case, since the upper and lower portions of the flow path are located in the rising part and the bottom part of the stirring object, the stirring efficiency stored in the tank as a whole is uniformly stirred to increase the stirring efficiency.

In addition, by combining the main hub and the auxiliary blade using the main blade formed in the main hub has an effect that can simplify the structure of the impeller.

In addition, the auxiliary blade is further formed on the outer surface of the auxiliary hub to form an additional swirl flow of the stirring object, thereby further increasing the stirring efficiency.

In addition, by forming the main blade and the auxiliary blade in an integrated structure, there is an effect that can increase the convenience of manufacturing the impeller.

In addition, if the flow path is extended to the outside of the stirring object, oxygen can be injected into the stirring object without a separate air injection device, thereby simplifying the structure of the equipment, and air bubbles ejected from the impeller are crushed by the auxiliary blade. As a result of increasing the contact efficiency of the air bubbles and the stirring object, through which there is an effect capable of more effective purification of the stirring object.

1 is a front view of a deep stirrer disclosed in Korean Patent No. 0921011,
2 is a front view of an agitator according to an embodiment of the present invention;
3 is an exploded perspective view of an impeller applied to a stirrer according to an embodiment of the present invention;
Figure 4 is a cross-sectional view of the impeller applied to the stirrer according to an embodiment of the present invention,
5 is a perspective view of the impeller further provided with an auxiliary blade;
6 is a cross-sectional view of the impeller further provided with an auxiliary blade;
7 is a front view of an agitator configured using an impeller further provided with an auxiliary blade;
8 is a front view of a multifunctional stirrer according to another embodiment of the present invention,
9 is a perspective view of an impeller applied to a multifunctional stirrer according to another embodiment of the present invention;
10 is a cross-sectional view of the impeller applied to the multifunctional stirrer according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Figure 2 is a front view of the stirrer according to an embodiment of the present invention, Figure 3 is an exploded perspective view of the impeller applied to the stirrer according to an embodiment of the present invention, Figure 4 is applied to the stirrer according to an embodiment of the present invention The cross section of the impeller is shown.

Multifunction stirrer according to the present invention is provided with a flow path (W) for the flow of the stirring object in the impeller 100, the flow path (W) is formed to extend from the upper layer to the lower portion of the stirring object to rotate the impeller (1000) The stirring object flowing through the upper end of the sieve flow passage (W) is accelerated by centrifugal force in the course of passing through the flow passage (W) to be ejected through the lower portion of the flow passage (W) at a high pressure, thereby providing a wider range. It has the characteristic that the stirring object can be mixed uniformly, and consists of the motor 30, the drive shaft 20, and the impeller 100. As shown in FIG.

The motor 30 generates power for rotating the impeller, and may be installed to be directly connected to the drive shaft 20 or may be installed to be connected to the drive shaft through a power transmission means such as a belt or a chain. 30 may include a reducer not shown.

The drive shaft 20 is coupled to the rotating shaft of the motor 30 and rotates, and extends vertically downward from the motor 30 is configured to be connected to the impeller 100.

Meanwhile, the impeller 100 according to the embodiment of the present invention includes a main hub 110, an auxiliary hub 120, an extension tube 130, and a main blade 140.

The main hub 110 is configured to have a shape such that the plate is rolled in a structure of upper and lower light (上 陜 下 廣) to constitute the body of the impeller 100. The main hub 110 is connected to the drive shaft 20 and rotates, and is configured in a cone shape having an extended diameter toward the lower end away from the drive shaft 20, preferably the outer surface (110a) is concave recessed It is formed to have a curved structure.

Like the main hub 110, the auxiliary hub 120 is formed to have a shape such as winding a plate in a conical shape, and is arranged to surround the main hub 110 while being spaced apart from the main hub 110 by a predetermined interval. It is to form a flow path (W) for the flow of the fluid between the hub (110). The auxiliary hub 120 is coupled to the main hub 110 is installed to rotate together with the main hub 110, wherein the separate hub as having a predetermined length for the coupling of the main hub 110 and the auxiliary hub 120 Although a coupling member may be used, when the upper end of the main blade 140 protruding from the main hub 110 is joined to the bottom surface of the auxiliary hub 120, the main hub 110 is not used without a separate coupling member. Since the coupling with the auxiliary hub 120 is possible there is an advantage that can simplify the structure of the impeller (100).

Like the main hub 110, the auxiliary hub 120 is formed in a cone shape of upper and lower light beams.

The extension pipe 130 is installed to extend vertically upward from the upper end of the auxiliary hub 120 to extend the flow path (W) to the upper layer of the stirring object. The extension tube 130 has a structure surrounding the drive shaft 20 while being spaced apart from the drive shaft 20 at a predetermined interval and is installed to extend along the drive shaft 20 to extend the flow path W to the upper layer of the stirring object.

Meanwhile, a perforated plate 131 connected to the drive shaft 20 is installed at the upper end of the extension tube 130.

The main blade 140 is formed in the main hub 110, the stirring object of the upper layer flows into the upper end of the flow path (W) when the impeller 100 rotates, the stirring object introduced into the flow path (W) tank It is to generate a pressure difference in the interior of the flow path (W) to be ejected near the bottom of the. The main blade 140 is composed of a plurality of, each main blade 140 is formed to protrude in a spiral structure on the outer surface of the main hub 110 is a flow path (W) for stirring the object during rotation of the impeller 100 Cycles).

The stirrer of the present invention configured as described above is installed so that the impeller 100 is located at the bottom of the tank, and the upper end of the extension tube 130 extending vertically upward from the auxiliary hub 120 is located at the upper layer of the stirring object. .

On the other hand, the impeller 100 located at the bottom of the tank is connected to the motor 30 via the drive shaft 20 to rotate, the flow path by the main blade 140 during the rotation by the drive of the motor 30 ( A negative pressure (-) is formed at the upper end of W) so that the stirring object in the upper layer flows into the flow path (W), and the stirring object flowing into the flow path (W) is centrifugal force in the process of flowing along the flow path (W). It is accelerated by, the accelerated stirring object is ejected at a high pressure to the lower end of the flow path (W).

As described above, the stirring object in the upper layer is introduced into the upper end of the flow path (W), and the stirring object introduced into the upper end of the flow path (W) is accelerated in the process of flowing along the flow path (W), and the accelerated stirring object is accelerated. Since it is ejected with a high pressure to the lower end of the flow path (W) of the, as shown in Figure 2 to form a high pressure swirl flow circulating through the tank as a whole, by such a swirl flow stirring efficiency of the stirring object in the tank It can be increased.

Meanwhile, in the case of the stirrer configured as described above, when the impeller 100 is rotated in the reverse direction by the reverse driving of the motor 30, the stirring object flows into the lower end of the flow path W, and thus, into the flow path W. The stirring object that is introduced rises along the flow path (W) and is discharged again through the extension pipe (130). Therefore, if the sludge settled on the bottom of the tank to rise again, if the impeller 100 is rotated back, the sludge flowing through the lower end of the flow path (W) is stirred through the upper end of the flow path (W) Since it is discharged back to the upper part of the sediment, it is possible to easily float the precipitated sludge.

5 is a perspective view of an impeller further provided with an auxiliary blade, FIG. 6 is a sectional view of an impeller further provided with an auxiliary blade, and FIG. 7 is a front view of an agitator configured using an impeller further provided with an auxiliary blade.

Meanwhile, the auxiliary blade 150 is further formed on the auxiliary hub 120 of the impeller 100 to form additional swirl flow to further increase the stirring efficiency.

More specifically, the auxiliary blade 150 is composed of a plurality, each of the auxiliary blades 150 is formed to protrude in a spiral structure on the outer surface of the auxiliary hub 120 is the auxiliary hub (when rotating the impeller 100 ( The stirring object in the periphery of the 120 is additionally flowed to form another swirl flow with the main blade 140, and thus the swirl flow S2 formed by the auxiliary blade 150 is formed by the main blade 140. It is possible to increase the stirring efficiency by increasing the collision rate between the stirring object to collide with the swirl flow (S1) is formed.

The auxiliary blade 150 as described above may be configured using the main blade 140 without forming a separate blade on the outer surface of the auxiliary hub 120. That is, the main blade 140 is formed on the main hub 110, and each main blade 140 is formed at a height sufficient to protrude to the outer surface of the auxiliary hub 120 through the auxiliary hub 120, When the secondary hub 120 forms a slot 121 through which the main blade 140 penetrates, the main blade 140 is assisted through the slot 121 when the main hub 110 and the auxiliary hub 120 are coupled to each other. Since the auxiliary blade 150 is formed by protruding to the outer surface of the hub 120, a separate operation for forming the auxiliary blade 150 is not required, thereby increasing convenience of manufacturing.

In addition, when the plurality of inlet holes 111 are further formed at the upper end of the main hub 110, the impeller 100 may be formed by the negative pressure (−) formed by the main blade 140 when the impeller 100 rotates. The stirring object located at the lower side is introduced into the flow path (W) through the inlet hole 111, so that the stirring efficiency can be further increased.

8 is a front view of a multifunction stirrer according to another embodiment of the present invention, FIG. 9 is a perspective view of an impeller applied to the multifunction stirrer according to another embodiment of the present invention, and FIG. 10 is another embodiment of the present invention. The cross section of the impeller applied to the multifunctional stirrer is shown.

The multifunctional stirrer according to the present embodiment is the same as the multifunctional stirrer described with reference to FIGS. 2 to 7 in that the motor 30, the drive shaft 20, and the impeller 100, the extension pipe of the impeller 100 130 is formed to extend to the outside of the stirring object to have a feature to inject external air into the stirring object without a separate air injection device.

Impeller 100 of the multifunction stirrer having this feature is composed of a main hub 110, an auxiliary hub 120, an extension pipe 130, and the main blade 140, this configuration is shown in FIGS. Same as the impeller 100 described with reference. However, the impeller 100 of the present embodiment has a difference in that the extension pipe 130 is configured to extend to the outside of the stirring object, and the auxiliary blade 150 is essentially installed on the outer surface of the auxiliary hub 120. .

As described above, since the components constituting the impeller 100 of the present embodiment are the same as the impeller 100 described with reference to FIGS. 2 to 7, the description of the same structure is omitted, and the same reference numerals are used. Do it.

Extension tube 130 of the previous embodiment is configured so that the upper end is located on the upper layer of the stirring object, the extension tube 130 of the present embodiment is formed so that the upper end protrudes out of the stirring object, flow by the extension tube 130 formed as described above Furnace (W) extends to the outside of the stirring object to form a flow path for the inflow of air.

The auxiliary blade 150 is composed of a plurality of, each auxiliary blade 150 is formed to protrude in a spiral structure on the outer surface of the auxiliary hub 120 to flow the stirring object when the impeller 100 rotates. The auxiliary blade 150 may be formed using the main blade 140 as described above.

Meanwhile, the main hub 110 and the auxiliary hub 120 are formed with a plurality of air discharge holes 112 and 122 for the flow of air and the stirring object, and the air discharge holes 112 and 122 formed as described above are flow-through (W). Inlet air is ejected to perform a nozzle function, in particular, the air bubbles formed by the air ejected from the air discharge hole 122 formed in the auxiliary hub 120 is finely broken by the collision with the auxiliary blade 150 As the contact area is increased and evenly dispersed into the inside of the stirring object, when the stirring object is waste water, there is an advantage of increasing the purification efficiency of the waste water.

As described above, the multifunction stirrer according to the present embodiment has an advantage of easy air injection without a separate air injection device.

Meanwhile, in the case of aquaculture fish farms, aberrations are used to supply oxygen necessary for the survival of fishes, and the aberrations have a problem of causing stress of fish due to noise generated when water drops, but according to the present invention, In this case, the noise is not generated due to the nature of injecting air directly into the water, which has the advantage of realizing a more ideal farming environment.

In addition, in the case of a waste water purification facility, a separate air injection device is not required, so the facility can be simplified, and an additive for purifying waste water can be introduced through the flow path (W). The additives added through the air are evenly mixed with the waste water together with the air to induce an active reaction, thereby further increasing the purification efficiency of the waste water.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

Description of the Related Art
110: main hub 111: inlet hole
(112): air exhaust hole (120): auxiliary hub
(121): slot 122: air vent
130: extension tube 140: main blade
150: secondary blade

Claims (7)

In the stirrer consisting of a motor 30, a drive shaft 20 extending from the motor 30 and rotated by the driving of the motor, and an impeller 100 provided on the drive shaft 20,
The impeller 100 may include: a main hub 110 connected to the drive shaft 20 and formed in a cone type having a diameter expanded as the drive shaft 20 moves away from the drive shaft 20;
The main hub 110 is spaced apart from the main hub 110 by a predetermined interval to form a flow path W for the flow of the fluid between the main hub 110 and the main hub 110. Coupled to rotate with the main hub 110, the auxiliary hub 120 formed of a cone type having a diameter extending from the upper end to the lower end;
It is installed on the upper end of the auxiliary hub 120, has a structure surrounding the drive shaft 20 while being spaced apart from the drive shaft 20 by a predetermined interval, is formed to extend along the drive shaft 20 to stir the flow path (W) Extension tube 130 extending to the upper layer of the object; And
It is formed to protrude spirally on the outer surface of the main hub 110, when the main hub 110 rotates, the fluid is introduced through the upper end of the flow path (W) and the fluid is discharged through the lower end of the flow path (W) Multifunctional stirrer, characterized in that consisting of a plurality of main blades 140. The method of claim 1,
The main hub 110 and the auxiliary hub 120 is a multifunctional stirrer, characterized in that coupled to each other via the main blade (140). The method of claim 1,
The impeller 100 further includes a plurality of auxiliary blades 150 spirally protruding from the outer surface of the auxiliary hub 120 to generate another swirl flow with the main blade 140. . The method of claim 3, wherein
The auxiliary blade 150 is a multi-function, characterized in that the main blade 140 formed in the main hub 110 is formed to protrude through the auxiliary hub 120 to be integral with the main hub 110. agitator. The method of claim 1,
Multifunctional stirrer, characterized in that the upper end of the main hub 110 is further formed with a plurality of inlet holes 111 for introducing the stirring object located in the lower portion of the impeller 100 into the flow path (W). The method of claim 1,
The extension pipe 130 of the impeller 100 is formed to protrude to the outside of the stirring object is configured so that the outside air flows into the flow path (W) between the main hub 110 and the auxiliary hub 120,
Multifunction stirrer, characterized in that the outer surface of the auxiliary hub 120 is formed to protrude in a spiral form a plurality of auxiliary blades (150) for flowing the stirring object when the auxiliary hub (120) rotates. The method according to claim 6,
Multi-function stirrer, characterized in that the main hub 110 and the auxiliary hub 120 is formed with a plurality of air discharge holes (112, 122) through which the air introduced through the flow path (W) is discharged.

Images