KR20160036545A - Areation Aapparatus - Google Patents

Abstract

The present invention relates to an aeration apparatus. The aeration apparatus comprises: a porous casing with a built-in motor; a mixing part positioned at the front of the casing, which is a space with an inlet hole; an impeller joined to a driving shaft so as to integrally rotate with the driving shaft of a motor extended to the mixing part, generating an outward flow in a radial direction when rotating while being positioned inside the mixing part; a tubular air inlet part which is a channel for air to flow into the mixing part, wherein an end part of one side is arranged to be positioned at the front of the impeller; and an outlet part formed in connection to the mixing part, discharging water and air mixed from the mixing part. In the mixing part (130), a plurality of projections (129) are formed to protrude so as to contact fluids. The aeration apparatus of the present invention can mix water and air for the second time by the projections formed in the outlet part as well as by the mixing part, and thus is capable of increasing rate of mixing water and air while increasing the amount of oxygen dissolved in water.

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.

Korean Patent Publication No. 10-1254873 (Apr. 19, 2013) discloses an aeration device. FIG. 1 is a side view showing a conventional aeration apparatus, FIG. 2 is a cross-sectional view showing a conventional aeration apparatus, and FIG. 3 is an exploded perspective view showing a conventional aeration apparatus.

Hereinafter, in FIG. 1, 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 transverse direction as 'longitudinal direction' The direction away from the drive shaft is called " radially outward ".

The aeration apparatus according to one embodiment of the present invention is installed in water such as sewage or wastewater, and is provided to discharge outside water into water by mixing external air with water in the water to mix the air. A mixing chamber 20 provided in a front side of the casing 10 and a mixing chamber 20 provided in the mixing chamber 20, A separating plate 40 provided on a front side of the mixing unit 20; a suction housing 50 provided on a front side of the separating plate 40; An air inflow portion 60 installed to penetrate the air inlet portion 60 to be an air inflow passage and a discharge portion 70 provided on the outer peripheral surface of the mixing portion 20.

A motor 13 is hermetically installed in the casing 10 and a driving shaft 16 of the motor 13 is disposed to face forward.

A lid portion 12 is provided at the rear of the casing 10 and a lid portion 15 and a wire 14 for supplying driving power to the lid portion 12 are provided do.

The mixing portion 20 is formed with a discharge hole 23 having a hollow cylindrical shape and opening in the circumferential direction.

The mixing unit 20 may be provided integrally with the casing 10 in front of the casing 10 so that the driving shaft 16 of the motor 13 is moved forward from the rear of the mixing unit 20 Lt; / RTI >

The drive shaft 16 is rotatably supported by a bearing portion 17 provided in the casing 10 and is disposed between the drive shaft 16 and the inner diameter of the mixing portion 20 in front of the bearing portion 17, A sealing portion 19 is provided.

The impeller 30 is provided on the drive shaft 16 so as to generate thrust in a radial direction of the mixing unit 20 and includes a disk plate 31 and a drive shaft 16 And a plurality of rotary vanes 32 protruding forward of the rotary plate 31. The support tab 33 is formed with an insertion hole 35 into which the rotary plate 31 is inserted. The support tab 33 protrudes forward and is spaced radially between the inner end of the rotary vane 32 and the support tab 33.

The impeller 30 is rotated by driving the motor 13.

The rotary vane 32 is formed radially and may be formed as a spiral so as to extend from the outer side of the rotary plate portion 31 toward the support tab portion 33 and have a convex curve outward in the radial direction.

The separation plate 40 is formed in a circular plate shape and has an inlet hole 41 penetrating through the center thereof in the forward and backward directions.

The suction housing 50 is formed as a plurality of suction holes 51 penetrating in the radial direction while being spaced apart in the circumferential direction as a cylindrical shape opened rearward. The suction hole 51 may be formed on the front surface of the suction housing 50.

The separation plate 40 is positioned between the suction housing 50 and the mixing unit 20. The size of the inflow hole 41 is smaller than the interval between the inner ends of the rotary vane 32. When the inflow hole 41 is formed in a circular shape, the size of the inflow hole 41 is formed to be smaller than the interval between the inner ends of the rotary vane 32.

The air inlet portion 60 includes a hollow inflow tab portion 61 penetrating from the front to the rear of the suction housing 50 and having one side and the other side opened and a second air inlet portion 61 connected to the front side of the inflow tab portion 61, And a hollow extension pipe portion 65 connected to the rear side of the inflowing tab portion 61 and extending toward the mixing portion 20. The hollow inflow pipe portion 63 has an open end, The extension tube portion (65) extends through the inflow hole (41). A gap is formed in the radial direction between the extension pipe portion (65) and the inflow hole (41).

A gap (t) is formed in the longitudinal direction between the rear end of the extension tube portion (65) and the support tab portion (33). One end portion of the inflow pipe portion 63 is exposed to the air to introduce air and the inflow air flows toward the impeller 30 through the inflow tab portion 61 and the extension pipe portion 65.

The mixing portion 20 is provided with a discharge portion 70 communicating with the discharge hole 23 on the outer peripheral surface.

The discharge portion 70 includes a hollow discharge tab portion 71 having one side and the other side opened to communicate with the discharge hole 23 and a hollow discharge pipe portion connected to the discharge tab portion 71 and having one side and the other side opened 73).

The discharge pipe portion 73 may include a large-diameter portion 74 forming the front half portion and a small diameter portion 75 forming the rear half portion.

In the conventional aeration device, air and water are mixed in the mixing portion and discharged through the discharge portion, the air introduced into the water is discharged in the form of large bubbles, the contact area between air and water in the water is reduced, There was a problem to be done.

Korean Registered Patent No. 10-1254873 (Apr. 19, 2013)

Disclosure of Invention Technical Problem [8] The present invention has been proposed in order to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide an air- And an object of the present invention is to provide an aeration device for preventing air pollution.

The aeration device according to the present invention comprises a hollow casing having a motor therein, a mixing section which is located in front of the casing and is a space formed with an inflow hole, and a mixing section which is coupled to the drive shaft so as to rotate integrally with the drive shaft of the motor extended to the mixing section, An air inflow portion which is located in front of the impeller and whose one end is a passage through which air flows into the mixing portion; And a discharge unit for discharging the mixed water and air from the mixing unit; And a plurality of protrusions protruding from the fluid are formed in the mixing portion.

The discharge unit may include a hollow discharge pipe portion having one end communicated with the mixing portion and the other end opened to the outside so as to communicate with the outside; And a plurality of protrusions protruded from the discharge tube portion.

In the above, a guide groove portion formed in the mixing portion and communicating with the discharge pipe portion and being concave and circumferentially formed is further included; And a plurality of projections are protruded from the guide groove.

In this case, the protrusions are positioned to be shifted from each other with respect to the flow direction.

The protrusions are formed by protrusions inserted into the protrusions from the outside.

 In the above, the cross section of the lower end of the projection member is a quadrangle consisting of two long sides and two short sides.

In the above, the central portion of the long side is formed to be concave.

The impeller includes a support tab portion protruding forward from a central portion of the impeller, the end portion of the drive shaft being screwed into the support tab portion; The auxiliary suction portion includes an extension shaft portion extending forward from the support tab portion and an auxiliary impeller portion provided at a front end portion of the extension shaft portion and allowing the fluid to flow backward when rotating.

The aeration device according to the present invention can mix the water and the air in the mixing part by the projections provided in the discharge part and then mix them again in the discharge process so that the contact area of water and air is prevented from being reduced during discharge, .

1 is a side view showing a conventional aeration apparatus,
2 is a cross-sectional view showing a conventional aeration device,
3 is an exploded perspective view showing a conventional aeration apparatus,
4 is a perspective view showing the aeration apparatus of the present invention,
5 is an exploded perspective view showing the aeration apparatus of the present invention,
6 is a cross-sectional view illustrating an operation state of the aerator of the present invention,
7 is a perspective view illustrating a casing, a separation plate, an impeller, and a discharge unit of the aerator of the present invention,
8 is a perspective view showing an impeller constituting an aerator of the present invention,
9 is a sectional view taken along the line AA in Fig. 7,
Fig. 10 is a sectional view taken along line BB of Fig. 9,
11 is a front view showing the projection member of the present invention,
12 is a bottom view of the projection member of the present invention,
13 is a sectional view of the lower end of the projection member of the present invention,
14 is a sectional modification of the lower end of the projection member of the present invention.

Hereinafter, an aeration apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 4 is a perspective view showing the aeration apparatus of the present invention, FIG. 5 is an exploded perspective view showing the aeration apparatus of the present invention, FIG. 6 is a sectional view for explaining an operation state of the aeration apparatus of the present invention, 7 is a perspective view showing a casing, a separation plate, an impeller, and a discharge unit of an aerator of the present invention, FIG. 8 is a perspective view showing an impeller constituting an aerator of the present invention, FIG. 9 is a cross- Fig. 12 is a bottom view of the projection member of the present invention, and Fig. 13 is a side view of the protruding member of the present invention. Fig. And Fig. 14 is a sectional modification of the lower end portion of the projection member of the present invention.

In the following description, the leftward direction is referred to as "forward", the rightward direction is referred to as "rearward", the forward direction to the rearward direction is referred to as "flow direction", the longitudinal direction is referred to as "radial direction" Direction away from the drive shaft is referred to as " radially outward ". The illustration of the internal structure of the motor is omitted in the drawing.

4 to 7, an aerator 100 according to the present invention includes a hollow casing 110 in which external air is introduced, mixed with water and discharged therefrom, and having a motor 113, The mixing unit 130 is disposed in front of the mixing unit 130 and is formed as a space in which the inlet hole 171 is formed and a driving shaft 131 of the motor 113 extending to the mixing unit 130. An impeller 150 which is connected to the mixing part 130 and generates a flow radially outwardly when rotating, and an impeller 150 whose one end is positioned in front of the impeller 150 to allow air to flow into the mixing part 130 And a discharge unit 120 formed to communicate with the mixing unit 130 and discharging mixed water and air from the mixing unit 130; The mixing unit 130 is provided with a plurality of protrusions 129 formed in contact with the fluid.

A motor 113 is provided in the casing 110 and a driving shaft 131 of the motor 113 extends forward toward the mixing unit 130. The end of the drive shaft 131 is positioned in the mixing portion 130. The rear of the casing 110 is provided with an openable and closable lid 111 integrally formed with the casing 110. The lid 111 is provided with an annular handle 115 and a motor 113 The electric wire 114 for supplying the driving power to the motor 113 is connected to the motor 113 through the cover 111. [

The mixing section 130 has a circular section. The mixing unit 130 is located in front of the casing 110 and is formed integrally with the casing 110. The mixing unit 130 may be formed separately from the casing 110. The mixing part 130 is formed in the front part of the motor 113 and is formed as a concave portion opened forward so that the front part of the casing 110 forms the mixing part 130. The mixing portion 130 is a space portion formed between a cylindrical portion that is opened concaved forward and a separation plate portion 170 that is coupled to an opened portion of the cylindrical portion. Water and air are mixed in the mixing portion 130. A guide groove 135 is formed in the rear surface of the mixing portion 130 in a circumferential direction concave.

The guide groove 135 is located at the radially outer edge. The guide groove 135 is formed in a circular arc shape along the circumferential direction of the rear surface of the mixing portion 130. The guide groove 135 is formed to be deeper and wider as it is closer to the discharge hole 133. The protrusion 129 is integrally provided in the casing 110, and a plurality of protrusions 129 protrude from the guide groove 135. The protrusion 129 may be formed by a protrusion 127 inserted into the casing 110 and protruding from the guide groove 135. The guide groove 135 communicates with the discharge pipe portion. A discharge hole 133 is formed between the guide groove part 135 and the discharge tube part. The guide groove portion 135 serves to guide the fluid to flow to the discharge pipe portion. The protrusion 129 mixes with air and acts as a resistor in the water.

The driving shaft 131 of the motor 113 is extended so that the front end thereof is positioned at the mixing portion 130. The drive shaft 131 is rotatably supported by a bearing portion 117 provided inside the casing 110. A sealing portion 119 is provided between the drive shaft 131 and the inner diameter of the casing 110 in front of the bearing portion 117. The sealing portion 119 prevents the water from penetrating into the casing 110.

The impeller 150 includes a rotating plate 151 and a plurality of rotating blades 152. The impeller 150 is coupled with the driving shaft 131 of the motor 113 extending to the mixing part 130 and is rotated in the mixing part 130 integrally with the driving shaft 131. The impeller 150 functions to generate a radial flow in the mixing portion 130 when the impeller 150 rotates. The impeller 150 is coupled to the driving shaft 131 to generate a thrust in a radial direction of the mixing part 130. The air introduced through the air inlet 190 and the water introduced through the inlet hole 171 of the separation plate 170 are mixed in the radial direction while being mixed by the rotation of the impeller 150. The driving shaft 131 protrudes forward through the center of the impeller 150 and the protruding portion of the driving shaft 131 is coupled to the driving shaft 131 by the supporting tab 153. The impeller 150 may be coupled to the drive shaft 131 of the motor 113 by welding or the like.

The rotary plate portion 151 has a circular section. A plurality of rotary vanes 152 projecting forward of the rotary plate 151 are radially formed in the rotary plate 151. A through hole through which the drive shaft 131 of the motor 113 passes is formed at the center of the rotation plate portion 151.

The rotary vane portion 152 is formed radially and is formed as a spiral so as to have a convex curve outward in the radial direction and protrudes forward. When the impeller 150 is rotated by the driving of the motor 113, the flow of the fluid is generated by the impeller 150.

The separation plate portion 170 has a circular section. And an inflow hole 171 penetrating in the front and rear direction is formed at the center portion. The diameter of the inflow hole 171 is larger than the inner diameter of the extension tube portion 195.

The suction housing 180 is cylindrical in cross section and open rearward. And is disposed in front of the mixing unit 130. [ A plurality of suction holes 181 are formed in the suction housing 180 so as to be spaced apart from each other in the circumferential direction and the longitudinal direction. The suction hole 181 may be formed on the front surface of the suction housing 180. And a suction housing 180 is coupled to the front of the separating plate portion 170. The suction housing 180 is coupled to the separating plate portion 170, which is spaced apart along the longitudinal direction.

The air inlet 190 has a hollow inflow tab portion 191 which is bent in a forward and backward direction through the suction housing 180 and has one side and the other side opened, And a hollow extension pipe portion 195 connected to the rear side of the inflow tab portion 191 and extending in the longitudinal direction toward the mixing portion 130. The hollow inflow pipe portion 193 extends in the radial direction. The air inlet 190 may be formed as an integral bent tube including an inflow tube 193 and an extension tube 195.

The inflow tab portion 191 is formed as a hollow structure having a bent structure. One side of the inflow tab portion 191 faces the mixing portion 130 and the other side faces outward in the radial direction. One side of the inflow tab portion 191 facing the mixing portion 130 is joined to the suction housing 180 by welding or the like. A hollow tube extension tube portion 195 is connected to one side of the inflow tab portion 191 and an inflow tube portion 193 which is a hollow tube is connected to the other side.

The extension tube portion 195 is circular in cross section and extends in the longitudinal direction to face the impeller 150. The extension tube portion 195 is positioned in the mixing portion 130 through the inlet hole 171. One end of the extension tube portion 195 faces the suction housing 180 and the other end faces the mixing portion 130. One side of the extension tube 195 is joined to the suction housing 180 by welding or the like.

The inflow tube portion 193 is circular in cross section and extends in the radial direction. One end portion of the inflow pipe portion 193 is exposed to the air during installation and air is introduced. The inflow air flows toward the impeller 150 via the inflow tab portion 191 and the extension pipe portion 195. The air introduced from the extension pipe portion 195 flows into the mixing portion 130 and is mixed with water in the mixing portion 130 and flows by the rotation of the impeller 150. The water and air are mixed and flowed and discharged to the discharge tube portion 121 through the guide groove 135 formed in the mixing portion 130.

The discharge unit 120 includes a hollow discharge pipe portion having one end communicating with the mixing portion 130 and the other end opened. The discharge unit 120 is a tube hollow body connected to the discharge hole 133 on the outer peripheral surface of the mixing unit 130. A plurality of protrusions 129 protrude from the discharge portion 120. The protrusion 129 may be formed by inserting the protrusion 127 outside the discharge unit 120. The protrusions 129 can be mixed again in the discharging process after the water and the air are mixed in the mixing portion to prevent the contact area between water and air from being reduced during discharge. As shown in FIG. 5, the projections 129 provided in the discharge unit 120 are positioned to be shifted from each other with respect to the flow direction. The projections 129 are spaced apart from each other so that the mixing of water and air can be performed more easily. The discharge portion communicates with the discharge hole 133 located in the casing 110 and is connected to the guide groove 135 of the mixing portion 130. Therefore, the air and water that have flowed through the guide groove 135 of the mixing unit 130 pass through the discharge hole 133 and are discharged through the discharge pipe portion.

As shown in FIGS. 9 and 10, the discharge pipe portion includes a first discharge pipe portion 121 and a second discharge pipe portion 125. The discharge pipe portion may be located on the outer peripheral surface of the mixing portion 130. The discharge pipe portion communicates with the discharge hole 133 located in the casing 110. The outlet pipe portion is connected to the casing 110 by a method such as a screw connection. The discharge pipe portion may be integrally provided in the casing 110. Air and water flowing through the guide groove 135 of the mixing part 130 pass through the discharge hole 133 and are discharged through the discharge pipe part. The first discharge pipe portion 121 and the second discharge pipe portion 125 are hollow (128) bodies having one side and the other side opened. One or more protrusions 129 are formed on the inner surface of the first exhaust pipe 121. The protrusion 129 may be formed by inserting a protrusion 127 from the outside. The protrusion 129 may be formed integrally with the first exhaust pipe 121. The discharge pipe portion is provided with a first discharge pipe portion 121 in the front half of the flow direction and a second discharge pipe portion 125 in the rear half. The second discharge pipe portion 125 is connected to the outside of the first discharge pipe portion 121 by welding, screwing, or the like.

7 and 8, the auxiliary suction portion 160 includes an extension shaft portion 161 extending forward from the support tab portion 153, and an auxiliary shaft portion 161 provided at the front end portion of the extension shaft portion 161, And an auxiliary impeller portion 162 for flowing the fluid to the rear side. The impeller 150 is provided with a support tab 153 protruding forward from the center and inserted into the end of the drive shaft 131 by screwing. The auxiliary suction unit 160 is provided in front of the impeller 150 so as to rotate integrally with the drive shaft 131 of the motor 113. A part of the front side of the auxiliary suction part 160 is inserted into the end of the air inlet part 190 rearward. The air inlet 190 is inserted into the rear end portion of the extension tube portion 195 when the air inlet portion 190 is formed of the extension tube portion 195. The auxiliary suction part 160 serves to rotate the fluid in the air inlet part 190 backward while rotating. The auxiliary suction unit 160 provides an additional suction force to the suction force generated by the rotation of the impeller 150 so that the water filled in the air inlet 190 is smoothly discharged to the rear at the initial stage of starting the aerator. Therefore, only air can be introduced from the air inlet 190 during start-up. The auxiliary suction portion 160 may be integrally formed with the impeller 150 or may be fastened to the drive shaft 131 of the motor 113 like a nut.

The extending shaft portion 161 is formed in a rod shape whose axial cross section is circular. The extension shaft portion 161 extends forward from the support tab portion 153 of the impeller 150. The auxiliary impeller portion 162 is provided at the front end portion of the extending shaft portion 161. The auxiliary impeller portion 162 may be formed integrally with the end of the extension shaft portion 161 or may be separately provided and may be fastened to the front end portion of the extension shaft portion 161 by screwing or the like.

The auxiliary impeller 162 is formed of a wing having a spiral structure that generates a flow in the axial direction while rotating. The auxiliary impeller portion 162 is integrally formed or connected to the end portion of the extending shaft portion 161 and connected thereto. The auxiliary impeller portion 162 is located in the rear end of the air inlet portion 190. The axial length of the sub-impeller portion 162 is smaller than the inner diameter of the air inlet portion 190. If the air inlet 190 is an extension tube 195, the auxiliary impeller 162 is positioned within the end of the extension tube 195 rearward. The auxiliary impeller 162 functions to flow the water in the air inlet 190 rearward at the initial stage of starting.

The support tab 153 is formed at the center of the impeller 150 and has a concave groove portion opened to the rear. The support tab portion 153 is formed at the center of the rotary plate portion 151 and protrudes forward, and is recessed to the rear and has a groove portion having a female thread portion. Therefore, the end of the drive shaft 131 is screwed and inserted into the support tab 153.

As shown in FIGS. 11 to 14, a plurality of protrusions 129 are formed in the discharge portion 120. The protrusion 129 may be integrally formed with the discharge part 120 and may be formed by a protrusion 127 inserted into the discharge part 120 and protruding into the discharge part 120. The projection member 127 is composed of a head 1271 of the projection member, a main body 1273 of the projection member, and a lower end portion 1275 of the projection member. The cross section of the lower end portion 1275 of the projection member may be a quadrangle consisting of two long sides 1275a and two short sides 1275b. In addition, the central portion of the long side 1275a may be concave. The cross section of the lower end portion 1275 of the projection member is not limited to those shown in Fig. 13 and Fig. 14, and may vary. The projection member 127 may be a screw or a screw. The projections 129 serve to mix water and air mixed in the mixing part 130 again to increase the mixing ratio of water and air. Therefore, the more the cross section of the lower end portion 1275 of the projection member becomes, the more effective it is. When various angles are formed, the vortex is more likely to occur due to the increase of the contact surface with the fluid, and when the vortex is generated much more, the water and the air are mixed more and the mixing rate becomes higher.

6 is a cross-sectional view illustrating an operating state of the aerator according to an embodiment of the present invention. Referring to Fig. 6, the aeration device is installed in the water such as sewage or waste water. The inflow pipe portion 193 is installed so that one end thereof extends outward from the water surface to receive outside air. The electric wire 114 is installed to extend out of the water surface because it is connected by a power source. When the driving shaft 131 is rotated by supplying power to the motor 113, the impeller 150 and the auxiliary suction unit 160 are rotated together to suck water in the water through the suction hole 181, 190 are flowed rearwardly by the auxiliary impeller portion 162 constituting the auxiliary suction portion 160 and are discharged from the air inlet portion 190. The water introduced into the suction housing 180 through the suction hole 181 flows into the mixing portion 130 through the gap between the inlet hole 171 and the extension pipe portion 195 of the separation plate portion 170, The water filled in the portion 190 is discharged to the rear and the air flows through the air inlet 190 and flows by the rotary vane 152. The impeller 150 and the auxiliary suction unit 160 are integrally rotated together with the rotation of the drive shaft 131 of the motor 113. [ The impeller 150 is rotated in the mixing portion 130 to allow the fluid to flow. Air and water are discharged through the discharge part 120 while the impeller 150 rotates. At this time, water and air are mixed again by the projections 129 inside the discharge part 120.

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.

100: Aeration device
110: casing 111: cover
113: motor 114:
115: Handle portion 117: Bearing portion
119: Sealing part
120: discharge part 121: first discharge pipe part
128: Through hole of discharge pipe
125: second discharge pipe portion 127: projection member
1271: projection member head 1273: projection member main body
1275: projection member lower end portion 1275a: long side of the projection lower end section
1275b: Short side of the lower end section of the projection 129:
130: mixing part 131: driving shaft of the motor
133: Exhaust hole 135: Guide groove
150: impeller 151:
152: rotary blade 153: support tie portion
160: auxiliary suction portion 161: extension shaft portion
162: auxiliary impeller part 170: separating plate part
171: Inflow hole 180: Suction housing
181: Suction hole 190: Air inlet
191: inflow tab portion 193: inflow tube portion
195: extension tube

Claims (8)

A mixing unit 130 which is a space in which the inlet hole 171 is formed and which is located in front of the casing 110 and a mixing unit 130 which is extended to the mixing unit 130, An impeller 150 coupled to the driving shaft 131 to rotate integrally with the driving shaft 131 of the impeller 113 and generating a flow radially outwardly in the mixing part 130 during rotation, An air inflow part 190 which is located in front of the mixing part 130 and serves as a passage through which air flows into the mixing part 130 and a mixing part 130 which is formed to communicate with the mixing part 130, (120) through which water and air are discharged; Wherein a plurality of protrusions (129) protruding from a fluid are formed in the mixing part (130). 2. The apparatus of claim 1, wherein the discharge unit (120) comprises a hollow discharge pipe portion having one end communicated with the mixing portion (130) and the other end opened to one side and the other to communicate with the outside; And a plurality of protrusions (129) are protruded from the discharge pipe portion. 3. The apparatus according to claim 1 or 2, further comprising a guide groove (135) formed in the mixing portion (130) and communicating with the discharge pipe portion and recessed in the circumferential direction; Wherein a plurality of protrusions (129) are protruded from the guide groove (135). The aeration device (100) according to any one of claims 1 to 3, characterized in that the projections (129) are positioned offset from each other with respect to the flow direction. The aeration device (100) according to claim 4, wherein the projection (129) is formed by a projection member (127) inserted from the outside and projecting inward. The aeration device (100) according to claim 5, wherein a cross section of the lower end portion (1275) of the projection member (127) is a quadrangle consisting of two long sides (1275a) and two short sides (1275b). The aeration device (100) according to claim 6, wherein the central portion of the long side (1275a) is concave. The motor according to claim 1, wherein the impeller (150) has a support tab portion (153) protruding forward from a central portion of the impeller (150) and an end of the drive shaft (131) The auxiliary suction portion 160 includes an extension shaft portion 161 extending forward from the support tab portion 153 and an auxiliary impeller 161 disposed at a front end portion of the extension shaft portion 161 to flow the fluid backward in rotation, (162). ≪ / RTI >

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