KR101569450B1 - Areation Aapparatus - Google Patents

Abstract

Disclosed is an aeration apparatus capable of controlling an inflow amount of air and improving mixing performance of water and air to improve aeration performance. A mixing section provided on a front side of the casing and formed with a discharge hole in a radial direction and having a driving shaft extending from the rear to a front side of the driving shaft; An impeller fixed to the drive shaft so as to generate a flow in a radial direction of the mixing portion, a suction housing installed at a front side of the mixing portion and having a plurality of suction holes, And an air control valve disposed in the air inlet and controlling an amount of air flowing through the air inlet. Accordingly, it is possible to control the inflow amount of air to efficiently perform aeration, and to improve the mixing performance of water and air, thereby improving the aeration performance.

Description

Aeration apparatus

The present invention relates to an aeration apparatus, and more particularly, to an aeration apparatus having a wastewater treatment efficiency improved by increasing a dissolved oxygen amount by aeration of wastewater during treatment of organic wastewater.

Generally, treatment of organic wastewater using microorganisms aeration wastewater. When the wastewater is aerated, the amount of dissolved oxygen in the wastewater is increased to activate the aerobic microorganisms, and the removal of suspended substances and noxious gases is promoted, thereby improving the effluent treatment efficiency. In fish farms, water is also aerated in the fish farm. In this case, the amount of dissolved oxygen is increased to prevent contamination of water, and the growth of live fish is promoted. It was also observed that green algae and flushing were prevented.

An aeration device has been disclosed in Korean Patent Registration No. 1254873 (Apr. 1 is a cross-sectional view showing a conventional aeration device. As shown in FIG. 1, the conventional aerator includes a cylindrical hollow casing 100, a mixing unit 200 provided on the front side of the casing 100, A separating plate 400 provided at a front side of the mixing unit 200 and a suction housing 500 provided at a front side of the separating plate 400. The suction housing 500 An air inflow part 600 installed to penetrate through the mixing part 200 to be an inflow passage for air and a discharge part 700 installed on the outer circumferential surface of the mixing part 200.

The motor 130 is enclosed in the casing 100 and the driving shaft 135 of the motor 130 protrudes forward. A lid 120 is provided at the rear of the casing 100. The lid 120 is provided with a handle 150 and a wire 140 for supplying driving power to the motor 130.

The mixing part 200 has a hollow cylindrical shape opened frontward, and a discharge hole 230 penetrating in the radial direction is formed on the circumferential surface. The driving shaft 135 of the motor 130 extends forward from the rear of the mixing portion 200. The driving shaft 135 is rotatably supported by a bearing portion 170 provided in the casing 100 and is disposed between the driving shaft 135 and the inner diameter of the mixing portion 200 in front of the bearing portion 170, (Not shown).

The impeller 300 is mounted on the driving shaft 135 so that a thrust is generated in the radial direction of the mixing unit 200 and includes a disk plate 310 and a supporting tab portion having an insertion hole into which the driving shaft 135 is inserted And a rotating blade unit 320 protruding forward of the rotation plate unit 310. The support tab portion 330 protrudes forward so that a gap is formed between the inner end of the rotation blade portion 320 and the support tab portion 330 in a radial direction. The impeller 300 is rotated integrally with the motor drive shaft 135 by driving of the motor 130.

The separation plate portion 400 is formed in a disk shape and has an inlet hole 410 penetrating through the center portion in the forward and backward directions. The suction housing 500 has a cylindrical shape that opens rearward and is formed with a plurality of suction holes 510 penetrating in the radial direction while being spaced apart in the circumferential direction. The separation plate portion 400 is located between the suction housing 500 and the mixing portion 200.

The air inflow portion 600 includes a hollow inflow tab portion 610 penetrating from the front to the back of the suction housing 500 and having one side and the other side opened and a second inflow portion 610 connected to the front side of the inflow tab portion 610, And a hollow extension pipe portion 650 connected to the rear side of the inflow tab portion 610 and extending toward the mixing portion 200. The hollow inflow pipe portion 630 has an open hollow inflow pipe portion 630, A gap (t) is formed in the longitudinal direction between the rear end of the extension tube portion (650) and the support tab portion (330).

The discharge unit 700 includes a hollow discharge tab unit 710 having one side and the other side opened to communicate with the discharge hole 230 and a hollow discharge pipe unit 730 connected to the discharge tab unit 710, . The discharge pipe portion 730 is composed of a large-diameter portion 731 forming the front half portion and a small diameter portion 735 forming the rear half portion.

In the conventional aeration device, water is filled in the inflow pipe portion 630 at the same height as the water surface before the driving, and the water filled through the inflow pipe portion 630 by the rotation of the motor 130 during the initial driving The air is sucked together with the water that has passed through the suction hole 510.

The conventional aerator has a problem in that the amount of air can not be controlled when mixing air introduced through the air inlet 600 and water introduced through the suction housing 500. In the mixing unit 200, There is a problem that the aeration performance deteriorates due to the poor mixing of air.

Patent Document: Korean Patent Publication No. 1254873 (Apr. 19, 2013)

In order to solve such a conventional problem, there is provided an aeration device capable of controlling the inflow amount of air and improving the mixing performance of water and air to improve the aeration performance.

The aeration device according to the present invention includes: a hollow casing having a motor therein; a mixing unit provided on a front side of the casing and having a discharge hole formed in a radial direction, the driving shaft of the motor extending through the front from the rear; An impeller rotatably installed in the mixing section and coupled to the driving shaft so as to generate a flow in a radial direction of the mixing section; a suction housing provided on the front side of the mixing section and having a plurality of suction holes; And an air inlet portion having an extension pipe portion extending through the air inlet portion and extending toward the impeller, and an air control valve provided in the air inlet portion to control the amount of air flowing through the air inlet portion.

In the above, a plurality of through holes, which are located in front of the impeller and are integrally rotated with the drive shaft, penetrate through the front and the rear, are formed to facilitate mixing of water and air during rotation.

In the above, the mixing promoting portion is formed in a mesh shape of a mesh structure.

In the above, the impeller is composed of a disk-shaped rotary plate and a plurality of rotary blades protruding forward of the rotary plate, and the blended promoter is fixedly coupled to the front end surface of the rotary blades.

The aeration apparatus according to the present invention can control the inflow amount of air to efficiently perform aeration and improve mixing performance of water and air to improve the aeration performance.

1 is a cross-sectional view showing a conventional aeration device,
2 is a side view showing an aeration apparatus according to an embodiment of the present invention,
3 is a cross-sectional view illustrating an aeration apparatus according to an embodiment of the present invention,
4 is an enlarged cross-sectional view of an impeller and a mixing promoting unit of an aerator according to an embodiment of the present invention,
5 is an exploded perspective view illustrating an aeration apparatus according to an embodiment of the present invention,
6 is an exploded perspective view showing an impeller and a mixing promoting unit of an aerator according to an embodiment of the present invention,
7 is a perspective view illustrating a state where an impeller and a mixing promoting unit of an aerator according to an embodiment of the present invention are combined,
FIG. 8 is an exploded perspective view showing the impeller and the mixing and promoting unit according to the modification of FIG. 6,
FIG. 9 is a cross-sectional view illustrating an operating state of an aerator according to an embodiment of the present invention.

Hereinafter, the technical configuration of the aeration device will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view illustrating an aeration apparatus according to an embodiment of the present invention. FIG. 4 is a cross-sectional view of the aeration apparatus according to an embodiment of the present invention. FIG. 5 is an exploded perspective view illustrating an aeration apparatus according to an embodiment of the present invention. FIG. 6 is a cross-sectional view of an impeller and a mixing section of an aerator according to an embodiment of the present invention. FIG. 7 is a perspective view illustrating a state where the impeller and the mixing promoting unit of the aerator according to the embodiment of the present invention are combined. FIG.

3, the leftward direction is referred to as 'forward', the rightward direction as 'rearward', the forward direction to the rearward direction as 'downstream direction', the longitudinal direction as 'radial direction', the lateral direction as 'longitudinal direction' The direction away from the drive shaft 9135 is referred to as " radially outward ". The illustration of the internal structure of the motor 913 is omitted in the drawing.

2 to 7, an aeration apparatus according to an embodiment of the present invention is installed in water and mixes and discharges external air into the water to be discharged therefrom. The apparatus includes a hollow casing 91, An impeller 93 disposed inside the mixing section 92 and a separation plate section 94 provided on the front side of the mixing section 92; An air inlet portion 96 provided to face the mixing portion 92 through the suction housing 95 and serving as an air inlet passage, A discharge part 97 installed to communicate with the mixing part 92 and discharging the mixed water and air and a discharge part 97 provided in front of the impeller 93 to rotate integrally with the driving shaft 135 of the motor 130 And an auxiliary suction portion (99).

The air inlet 96 is formed of a portion extending in the longitudinal direction and a portion extending in the radial direction. The radially extending portion is not limited to the one vertically extending from the portion extending in the longitudinal direction. The portion extending in the longitudinal direction may be inclined at an obtuse angle or an acute angle with respect to the portion extending in the longitudinal direction It is also possible to extend.

A motor 913 is provided in the casing 91 and a driving shaft 9135 of the motor 913 extends toward the mixing portion 92 toward the front. The end of the drive shaft 9135 is located in the mixing portion 92. An opening / closing lid portion 912 integral with the casing 91 is screwed to the rear of the casing 91. An annular handle 915 is provided on the lid portion 912 and a motor 913 The electric wire 914 for supplying the driving power to the motor 913 is connected to the motor 913 through the lid portion 912. [

The mixing portion 92 may be formed as a recess formed in the front of the motor 912 and open toward the front so that the front portion of the casing 91 forms the mixing portion 92. The mixing portion 92 is a space portion formed between a cylindrical portion that is opened concaved forward and a separation plate portion 94 that is coupled to an open portion of the cylindrical portion. A discharge hole 923 penetrating the circumferential surface of the cylindrical portion constituting the mixing portion 92 is formed. The discharge hole 923 is formed in a circumferential direction and at an inclined angle. A cylindrical portion inside the mixing portion 92 is provided with a discharge hole 923 along the circumferential direction guiding the fluid to flow through the discharge hole 923 A concave groove is formed. In front of the mixing portion 92, a through hole penetrating through the center portion is formed. The through hole may be formed as an inflow hole 941 in the separation plate portion 94.

The mixing section 92 is disposed in front of the casing 91. And the driving shaft 9135 of the motor 913 is extended from the rear by the mixing portion 92. [ The mixing section 92 may be formed integrally with the casing 91 in front of the casing 91 and the driving shaft 9135 of the motor 913 may be provided with an extension do.

The drive shaft 9135 is rotatably supported by a bearing portion 917 provided inside the casing 91 and is provided between the drive shaft 9135 and the inner diameter of the casing 91 in front of the bearing portion 917, 919).

The impeller 93 is rotatably installed in a mixing portion 92 provided on a driving shaft 9135 extending integrally with the driving shaft 9135 of the motor 913 and extending to the mixing portion 92, So that a flow in the radial direction is generated in the second flow path 92. The impeller 93 is coupled to the drive shaft 9135 so as to generate a thrust in the radial direction of the mixing portion 92 and includes a disk plate 931 and a plate portion 931 protruded forward And may include a plurality of rotating blades 932. The impeller 93 is not limited to the above-described configuration, and a structure for generating fluid flow radially outward is possible.

The air introduced through the air inflow portion 96 and the water introduced through the inflow hole 941 of the separation plate portion 94 flow in the radial direction while being mixed by the rotation of the impeller 93.

The rotary wing portion 932 is formed radially and is formed into a spiral so as to have a convex curve outward in the radial direction and protrudes forward. When the impeller 93 is rotated by the driving of the motor 913, the flow of the fluid is generated by the impeller 93 in the radial direction substantially perpendicular to the driving shaft 9135.

The separation plate portion 94 is formed in a circular plate shape and has an inlet hole 941 penetrating through the center portion in the forward and backward directions. The size of the inflow hole 941 is formed to be smaller than the interval between the inner ends of the rotary vane portion 932. When the inlet hole 941 is formed in a circular shape, the size of the inlet hole 941 is formed to be smaller than the interval between the inner ends of the rotary vane portion 932.

The suction housing 95 is formed in a cup shape that opens rearward and is disposed in front of the mixing section 92. The cylindrical section is provided with a plurality of suction holes 951 Is formed. The suction hole 951 may be formed on the front surface of the suction housing 95. And a suction housing 95 is coupled to the front of the separation plate portion 94. The suction housing 95 is engaged with the separation plate portion 94 by a bolt-nut fastening which is spaced apart in the circumferential direction. The cup-shaped bottom portion is spaced forwardly from the separation plate portion 94. The end surface of the suction housing 95 is not limited to a circular shape but may be formed in a polygonal shape.

The aeration device according to the embodiment of the present invention is installed in the water and when the motor 913 is driven, the flow of the fluid radially outward due to the rotation of the impeller 93 occurs, The water in the water is sucked into the suction hole 951 and foreign substances larger than the suction hole 951 are blocked from being introduced by the suction housing 95. The water introduced through the suction hole 951 flows into the mixing portion 92 through the inlet hole 941 of the separation plate portion 94.

The air inlet 96 extends through the bottom surface of the suction housing 95 from the front to the rear. The air inlet portion 96 has a portion radially extending from the outside of the suction housing 95 toward the mixing portion 92 through the suction housing 95 in the longitudinal direction. However, the present invention is not limited to this, and it is also possible to adopt a structure in which the side surface of the suction housing 95 extends from the front to the rear. The air inflow portion 96 has a hollow inflow tab portion 961 having a bent structure and an inflow tube portion 963 which is a hollow tube is connected to the extension tube portion 965 which is a hollow tube to one side of the inflow tab portion 961, Can be connected. When installed, the extension tube portion 965 extends in the longitudinal direction toward the impeller 93, and the inlet tube portion 963 extends in the radial direction. The end of the extension tube portion 965 may be positioned in front of the separation plate 94 adjacent to the inlet hole 941 and may be located in the mixing portion 92 through the inlet hole 941. [ The inlet tab portion 961 is fixed to the suction housing 95 by welding or the like so that one side thereof faces the mixing portion 92 and the other side faces the radially outward side. The inflow tab portion 961 may be disposed between the bottom portion of the suction housing 95 and the separation plate portion 94 and the inflow tube portion 963 may be installed to penetrate the cylindrical portion of the suction housing 95 in the radial direction. In this case, the inlet tube portion 963 and the cylindrical portion of the suction housing 95 are coupled by welding or the like.

The air inflow portion 96 includes a hollow inflow tab portion 961 having a bent structure with one side and the other side being opened and extending from the front side to the rear side of the suction housing 95 and a hollow inflow tab portion 961 connected to the front side of the inflow tab portion 961 A hollow inflow tube portion 963 extending in the radial direction and a hollow extension tube portion 965 connected to the rear side of the inflow tab portion 961 and extending in the longitudinal direction toward the mixing portion 92.

The extension tube portion 965 extends rearwardly through the inflow hole 941. A gap is formed between the extension tube portion 965 and the inflow hole 941 in the radial direction. One end portion of the inflow pipe portion 963 is exposed to the air to introduce air, and the inflow air flows toward the impeller 93 through the inflow tab portion 961 and the extension pipe portion 965. The air introduced from the extension pipe portion 965 flows into the mixing portion 92 and is mixed with water in the mixing portion 92 and flows radially by the rotation of the impeller 93. The water and the air are mixed and radially flowed and discharged through the discharge hole 923 formed in the mixing portion 92.

The discharge portion 97 is a hollow body that is a tube connected to the discharge hole 923 on the outer circumferential surface of the mixing portion 92. The discharge portion 97 is a hollow body which is connected to the mixing portion 92 through the discharge hole 923, And is discharged through the discharge portion 97. The discharge portion 97 includes a hollow discharge tab portion 971 coupled to the discharge hole 923 by a screw or the like and a hollow discharge pipe portion 973 connected to the discharge tab portion 971. The discharge tube portion 973 may include a large diameter portion 9731 forming the front half portion and a small diameter portion 9735 forming the rear half portion and the flow cross sectional area of the small diameter portion 9735 is formed smaller than the flow cross sectional area of the large diameter portion 9731 .

Therefore, when a fluid such as water flows into the discharge tube portion 973 and the fluid that has flowed through the large-diameter portion 9731 flows into the small-diameter portion 9735, the cross-sectional area of the small-diameter portion 9735 is smaller than the cross- A relatively high pressure is formed in the large-diameter portion 9731, and a relatively low pressure is formed in the small-diameter portion 9735. [

The impeller 93 is coupled to the driving shaft 9135 of the motor 913 so that the impeller 93 rotates together with the driving shaft 9135. The driving shaft 9135 penetrates the central portion of the impeller 93 and protrudes forward to form a male thread on the protruding portion and is fastened with a nut so that the impeller 93 can be coupled to the driving shaft 9135. The rear side of the impeller 93 is supported and supported by a support structure such as a step formed on the drive shaft 9135. [ The impeller 93 may be coupled to the drive shaft 9135 of the motor 913 by a welding method.

The auxiliary suction portion 99 extends forward of the impeller 93 and extends to the inside of the extension pipe portion 965 so that the auxiliary suction portion 99 rotates together with the drive shaft 9135 and the impeller 93 of the motor 913, Thereby generating a flow in the fluid from the inside to the rear. The auxiliary suction portion 99 is constituted by an extension shaft portion 991 and an auxiliary impeller portion 992. The impeller (93) has a support tab portion (933). The auxiliary suction unit 99 provides an additional suction force to the suction force generated by the rotation of the impeller 93 so that the water filled in the air inlet 96 is smoothly discharged to the rear at the beginning of the aeration apparatus.

The aeration apparatus according to an embodiment of the present invention further includes an air control valve 967. The air control valve 967 is provided in the air inlet 96 and the air control valve 967 can be installed on the inlet pipe 963. The air control valve 967 may be installed in the inflow tab portion 961 or the extension tube portion 965, but is preferably installed in the inflow tube portion 963. The air control valve 967 functions to control the amount of air flowing through the air inlet 96. The amount of air flowing through the inflow pipe portion 963 can be controlled through the configuration of the air control valve 967, thereby aeration can be efficiently performed.

In addition, the aeration apparatus according to an embodiment of the present invention includes a mixing promoting unit 939. The mixing promoting portion 939 is located in front of the impeller 93 and is fixedly coupled to the front end surface of the rotating blade portion 932 of the impeller 93. The mixing promoting portion 939 may be fixedly coupled to the extension shaft portion 99 of the auxiliary suction portion 99. The mixing promoting portion 939 is provided so as to rotate integrally with the driving shaft 9135.

The mixing facilitating part 939 has a circular plate shape having a predetermined width in the forward and backward directions, and has a plurality of through holes 9391 penetrating through the front and rear. The mixing promoter 939 may have a mesh network structure. The mixing facilitating part 939 is formed in a net shape to form a plurality of through holes 9391. FIG. 8 is an exploded perspective view showing the impeller and the mixing promoting unit according to the modification of FIG. 6. As shown in FIG. 8, the mixing promoting unit 939 has a structure in which a plurality of through holes 9391 are formed in a disc- .

The mixing facilitating part 939 is integrally rotated together with the driving shaft 9135 and the impeller 93 and flows into the suction housing 95 through the air introduced through the air inlet 96 and the suction hole 951 Thereby promoting the mixing of water. Thus, through the composition of the mixing promoter 939, the mixing efficiency of water and air can be increased and the aeration efficiency can be improved.

FIG. 9 is a cross-sectional view illustrating an operating state of an aerator according to an embodiment of the present invention. Referring to Fig. 9, the aeration device is installed in water. The air inflow portion 96 is installed so that one end portion extends outward from the water surface to receive outside air. When the driving shaft 9135 is rotated by supplying power to the motor 913, the impeller 93 and the auxiliary suction unit 99 rotate together to suck water in the water through the suction hole 951, 96 flows rearward and is discharged from the air inflow portion 96.

The water introduced into the suction housing 95 through the suction hole 951 flows into the mixing portion 92 through the gap between the inlet hole 941 and the extension pipe portion 965 of the separation plate portion 94, As the water filled in the portion 96 is discharged to the rear, air flows in through the air inlet portion 96 and flows in the radial direction by the rotary vane portion 932. By the rotation of the impeller 93, air and water are radially discharged by the radial thrust of the impeller 93 and discharged through the discharge hole 923.

The impeller 93 and the auxiliary suction unit 99 rotate together with the rotation of the drive shaft 9135 of the motor 913 and the auxiliary impeller unit 992 constituting the auxiliary suction unit 99 is rotated by the air inlet 96 So that the fluid flows backward in the air inlet 96 while the impeller 93 rotates in the mixing portion 92 to allow the fluid to flow radially outward.

The air control valve 967 provided in the inflow pipe portion 963 regulates the amount of air introduced through the inflow pipe portion 963. The air introduced through the inflow pipe portion 963 and the water introduced into the suction housing 95 through the suction hole 951 are mixed by the rotation of the impeller 93 and are guided to flow in the radial direction, And the mixing facilitating part 939 which rotates together at the front end of the impeller 93 promotes mixing of water and air, thereby further improving the aeration performance.

In the above description, the aerator is installed in the water, but it is installed separately from the water. In the same manner as described above, the impeller 93 is rotated to introduce the wastewater into the suction housing 95 through a separate pipe It is possible to realize a structure in which water and air discharged through the discharge part 97 are sent to the waste water side by mixing with the air and discharging through the discharge part 97.

While the aeration apparatus according to the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that various changes and modifications may be made by those skilled in the art without departing from the scope of the present invention. Accordingly, the scope of the true technical protection should be determined by the technical idea of the appended claims.

91: casing 913: motor
9135: drive shaft 92: mixing part
923: Exhaust hole 93: Impeller
931: Rotating plate part 932: Rotating blade part
933: Support tab portion 94: Separation plate portion
941: Inflow hole 95: Suction housing
951: suction hole 96: air inlet
961: inflow tab portion 963: inflow tube portion
965: extension tube portion 97:
99: auxiliary suction part 991: extension shaft part
992: auxiliary impeller part 967: air regulating valve
939: Mixing facilitating part 9391: Through hole

Claims (4)

Which is a space in which a discharge hole 923 is formed in a radial direction and which is located forward of the casing 91 and in which an inflow hole 941 is formed forwardly, a hollow casing 91 in which a motor 913 is embedded, 92 and a driving shaft 9135 of the motor 913 extended to the mixing portion 92 so as to be integrated with the driving shaft 9135 so as to be located in the mixing portion 92 and generate a flow radially outward And an air inflow portion 96 which is provided at one end of the impeller 93 in front of the impeller 93 and serves as a passage through which air flows into the mixing portion 92; And an air control valve (967) provided in the air inlet (96) for controlling the amount of air flowing through the air inlet (96);
A plurality of through holes 9391 disposed in front of the impeller 93 and integrally rotating with the driving shaft 9135 and passing through the front and the rear of the impeller 93 to facilitate mixing of water and air during rotation, (939). ≪ / RTI > delete The aeration device according to claim 1, wherein the mixing facilitating part (939) has a mesh network structure. The impeller according to claim 1, wherein the impeller (93) comprises a disk-shaped rotating plate portion (931) and a plurality of rotating blade portions (932) protruding forward of the rotating plate portion (931) Wherein the mixing facilitating part (939) is fixedly coupled to the front end surface of the rotary vane part (932).

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