KR100965275B1 - Sprinkling water devices for sewage and wastewater treatment - Google Patents

Abstract

The present invention relates to a sprinkling device for aeration and agitation of sewage and wastewater, and the agitation and exhalation of sewage and wastewater during sewage and wastewater treatment through a single watering device having a watering drive motor, an impeller, a watering pipe, and a watering induction pipe. The purpose is to enable the aerobic reaction of the microorganism to be performed smoothly by selectively performing aeration for supplying oxygen according to the conventional reaction treatment. The present invention configured for this purpose is a sprinkling drive motor configured to be capable of forward and reverse rotation; A housing means configured at a lower portion of the sprinkler driving motor to enable installation and fixing on the structure; An impeller connected to the motor shaft of the watering and driving motor to pull up the wastewater inside the microbial reactor through the forward and reverse rotation to make aeration or to send the wastewater downward to stir the organic matter contained in the wastewater into contact with the microorganism; A watering means configured to penetrate the center of the impeller so as to be installed at a lower portion of the housing means to sprinkle the wastewater pulled upward by the impeller at a predetermined angle to allow aeration; The sprinkling induction cone of the inverted triangular shape is coupled to the upper side on the impeller shaft is installed between the sprinkling means is rotated at the same rotational speed as the impeller to guide the wastewater pulled upward at a certain angle; And a wastewater induction pipe that is fixedly coupled to the lower portion of the watering means and is formed in a fallopian tube shape that extends from a predetermined portion downward to a lower portion, thereby directing the wastewater upward or downward by forward and reverse rotation of an impeller located therein.

Microbial reaction tank, watering, aeration, stirring

Description

Sprinkling water devices for sewage and wastewater treatment}

The present invention relates to a sewage treatment device for sewage and wastewater treatment, and more particularly, to provide an aeration for supplying oxygen according to agitation and aerobic reaction treatment of sewage and wastewater during sewage and wastewater treatment. It relates to a sprinkling apparatus for sewage and wastewater treatment, which can selectively perform one agitation and aeration provided with a watering induction pipe.

It is well known that there was a lack of awareness of environmental conservation in the course of rapid economic development. As a result of the lack of awareness of environmental preservation, the level of pollution as well as air quality has reached a very serious level.In particular, municipal sewage, agricultural and livestock wastes, and industrial wastes are appealing, public waters such as inland waters and inland seas. It is a cause of polluting the water quality of small and medium rivers.

Therefore, the achievement rate of chemical oxygen demand (COD) and biochemical oxygen demand (BOD), which are related to total nitrogen (N) and total phosphorus (P) such as appeal due to water pollution, internal bay and inland sea, as described above, Very low condition. Moreover, since rivers, lakes and dams are often sources of drinking water, mold odors, filter disturbances, and abnormal propagation of toxic algae have emerged as major environmental issues.

On the other hand, while the contaminants of conventional sewage, agricultural and livestock waste, and industrial wastewater are mainly organic substances that can be decomposed by certain microorganisms, in recent years, due to rapid industrial development, population growth, and urban population concentration, With the increase, the proportion of inorganic and organic components in the wastewater is gradually increasing.

In the domestic treatment of sewage, agricultural and livestock waste, and industrial wastewater as described above, the standard activated sludge method using the microbial floating growth and its variations are almost universally used. However, the existing activated sludge method has problems that it is difficult to remove nitrogen and phosphorus, which are the main pollutants of eutrophication, in public waters such as lakes, inner bays and inland seas, and small and medium cities.

As mentioned above, contaminants such as household sewage, agricultural and livestock wastewater, and industrial wastewater, which have not been properly treated, have been rapidly discharged into rivers and have rapidly polluted most water sources. Due to such pollution, nutrients and organic substances such as ammonia nitrogen and phosphorus in water have a great environmental problem due to mold odor, filter disorder and abnormal growth of toxic algae.

In particular, the livestock wastewater is less than the sewage or industrial wastewater in terms of discharge, but can not be overlooked in terms of pollution, that is, the pollutant load, and the pollution degree of livestock wastewater in the state where the sediment is separated is BOD (Biological Oxygen Demand, or 4,000 to 5,000 ppm, if not separated, will exceed 20,000 ppm.

On the other hand, manure of livestock wastewater is easily dried when mixed with sawdust, and it is less likely to flow into rainwater even if it rains, and it is easy to compost, so it is not difficult to treat livestock wastewater. Iii) is not easy to dry, so it is not easy to separate it. Therefore, most of the water pollution caused by livestock wastewater is mainly made by manure of pigs, and in order to solve this problem, the government has set up a livestock wastewater treatment facility with enormous funds, but it does not operate properly. That is, the livestock wastewater treatment facility is not properly operated because of overloading due to side effects such as the design and actual concentrations of livestock wastewater flowing into the facility appear to show a sharp gap.

Therefore, the livestock wastewater treatment facility of the method as described above has a problem of cost burden for maintaining the livestock wastewater treatment facility because the scale is very large.

In addition, in the case of industrial wastewater, the amount of wastewater generated is not only large, but also has high concentrations of organic and suspended solids, and contains chromium and sulfide, which are not suitable for biological treatment. Biological treatment is performed after pretreatment such as neutralization and flocculation sedimentation, and a large amount of sludge is generated. In addition, there is a severe odor problem and difficulties in the treatment of the wastewater wastewater is urgently required to develop a countermeasure and effective treatment method.

As described above, in order to satisfy the water quality regulation by applying a single treatment method in a situation where the inflow of inflow water is not constant, there is a problem that excessive treatment costs are required. It is used complementarily. That is, recently, as a sewage and wastewater treatment method, a physical method, a chemical method, and a biological method have been fused and applied in a complementary manner.

When treating sewage / wastewater by biological treatment method among the above-mentioned wastewater / wastewater treatment methods, the nitrification process of organic matter by microorganisms is caused by contacting microorganisms and organic matter under aerobic conditions for wastewater undergoing anaerobic digestion and denitrification. The organic matter and ammonia nitrogen is removed through the waste water purification process, and the oxygen supplying device is an aeration device.

However, the aeration device according to the prior art is composed of a distribution pipe for distributing the blower and air and an aeration pipe for forming air bubbles to supply oxygen during the exhalation process, so that the installation of the aeration device in the aeration tank is complicated. have. In addition, the aeration device according to the prior art has a problem that the burden of the cost increases due to the need for a plurality of blowers when the size of the waste water treatment device is large.

In addition, since the aeration device according to the prior art only supplies oxygen required by the microorganisms, it is not possible to stir the wastewater in order to facilitate contact between the microorganisms and the organic matter, so a separate stirrer must be installed to stir the wastewater. There is a problem. Therefore, there is a problem that a separate cost burden occurs because a separate device for stirring the waste water.

In order to solve all the problems of the prior art as described above of the present invention, the sewage driving motor and impeller, the watering pipe and the watering through a single watering device equipped with a watering induction pipe of sewage and wastewater treatment It is an object of the present invention to provide a sewage treatment device for sewage and wastewater that enables aerobic reaction of microorganisms to be performed smoothly by selectively performing aeration for supplying oxygen according to stirring and aerobic reaction treatment.

Another object of the technology according to the present invention is to provide oxygen according to agitation and aerobic reaction treatment of sewage and wastewater through a watering device equipped with a watering drive motor, an impeller, a watering pipe, and a watering induction pipe. The purpose of the present invention is to simplify the facilities for agitation and aeration of sewage and wastewater by selectively performing aeration to be supplied, thereby reducing costs associated with the facilities of sewage and wastewater treatment plants.

In addition, another object of the present invention is to provide a sewage treatment device for sewage and wastewater treatment so that the surface of the wastewater flows up and down during aeration or agitation of the wastewater.

The present invention is configured to achieve the object as described above is as follows. In other words, the sewage treatment system for sewage and wastewater according to the present invention is a device for supplying oxygen to the wastewater inside the microbial reaction tank to purify the wastewater by the microbial reaction under aerobic conditions, the sprinkling is configured to be reverse rotation Drive motor; A housing means configured at a lower portion of the sprinkler driving motor to enable installation and fixing on the structure; An impeller connected to the motor shaft of the watering and driving motor to pull up the wastewater inside the microbial reactor through the forward and reverse rotation to make aeration or to send the wastewater downward to stir the organic matter contained in the wastewater into contact with the microorganism; A watering means configured to penetrate the center of the impeller so as to be installed at a lower portion of the housing means to sprinkle the wastewater pulled upward by the impeller at a predetermined angle to allow aeration; The sprinkling induction cone of the inverted triangular shape is coupled to the upper side on the impeller shaft is installed between the sprinkling means is rotated at the same rotational speed as the impeller to guide the wastewater pulled upward at a certain angle; And a wastewater induction pipe that is fixedly coupled to the lower portion of the watering means and is formed in a fallopian tube shape that extends from a predetermined portion downward to a lower portion, thereby directing the wastewater upward or downward by forward and reverse rotation of an impeller located therein.

In the configuration of the present invention as described above, the housing means is formed in a disk shape, but a plurality of coupling grooves are formed at a predetermined interval to be fixed to the disk-shaped fixed member installed in the lower portion of the sprinkler driving motor; A housing main body which is formed in a cylindrical shape so that the impeller penetrates and is formed to have a predetermined length up and down; A plurality of coupling grooves corresponding to the coupling grooves of the fixing member, the upper connection pieces being integrally formed on the upper edge of the housing body; And a lower connection piece which is integrally formed on the lower edge of the housing body and has a coupling groove at a predetermined interval for connecting and supporting the watering means.

In the configuration of the present invention as described above, the fixing piece is formed integrally on the upper connection piece of the housing means, the fixing piece for fixing the sewage treatment device for sewage treatment on the structure may be further configured. .

In the configuration of the present invention as described above, the impeller may have a screw-shaped blade formed on the shaft of a predetermined length in a double or triple, but the screw groove is formed on the outer peripheral surface of the upper side of the impeller shaft.

On the other hand, the above impeller is coupled to the motor shaft of the sprinkling driving motor through the coupling, the coupling is a motor shaft coupling portion coupled to the motor shaft of the sprinkling driving motor; An impeller coupling portion having threaded holes formed at both sides corresponding to a coupling hole having a diameter corresponding to the impeller shaft and a screw groove formed at the impeller shaft; And it is formed on the lower outer periphery of the impeller coupling portion may be made of induction cone coupling coupled to the upper surface of the sprinkler guide cone coupled to the impeller is formed by a coupling hole at a predetermined interval.

The watering means in the configuration of the present invention as described above is a support body of a predetermined thickness is formed in the center of the sprinkling through-hole is reduced to a lower portion around the sprinkling through-hole at regular intervals; A sprinkling plate which is installed at a predetermined interval on an upper portion of the supporter and allows the wastewater drawn up upward by the impeller to be sprinkled at a predetermined angle; A spacing member installed at a predetermined interval at the edge of the support and the watering plate to maintain a distance between the support and the watering plate; And it may be made of a fastening means for fastening and coupling through the support and the spacer and spacing plate.

And, in the configuration of the above-mentioned watering means, the watering plate is plate-shaped plate body which is formed to support a plurality of coupling holes corresponding to the coupling hole of the lower connection piece is coupled to the housing body lower portion through the coupling member; A shaft through hole formed through a predetermined diameter such that the shaft of the impeller penetrates the center of the plate body; And a wastewater scattering groove which is formed at a predetermined interval on the outer periphery of the plate body to be discharged and scattered at a predetermined angle by the wastewater pulled up by the impeller, and the watering plate is a coupling hole of the lower connection piece. Plate-shaped plate body that is formed in a plurality of coupling holes corresponding to the support coupled to the housing body lower portion through the coupling member; A shaft through hole formed through a predetermined diameter such that the shaft of the impeller penetrates the center of the plate body; And it may be made of a configuration of the spout hole is formed to penetrate at a predetermined interval on the outer periphery of the shaft through-hole of the plate body to be discharged upward by the impeller.

In the configuration of the present invention as described above, the sprinkler induction cone shaft hole through which the impeller shaft is coupled through its center; A coupling coupling portion in which a plurality of coupling holes corresponding to the coupling holes formed in the induction cone coupling portion of the coupling are formed; And formed integrally at the lower portion of the coupling coupling member, the cone shape of which is gradually reduced in diameter toward the lower portion, so that the wastewater drawn upwardly through the sprinkling through hole of the support can be sprayed at a predetermined inclination angle through its outer peripheral surface. It can be made of salcon. At this time, the sprinkling induction cone is located in the center between the support and the sprinkling plate and the lower part is inserted into the sprinkling through-hole of the support, but is inserted so as to be spaced apart from the inner circumferential surface of the sprinkling through-hole at a predetermined interval to spray the wastewater. By guiding upward through the outer circumferential surface of the induction cone, the guided wastewater may be made to be configured to be sprayed scattered while hitting the lower surface of the sprinkling plate.

Wastewater induction pipe in the configuration of the present invention as described above is aeration induction pipe made of a predetermined size to induce wastewater on the microbial reactor through the inside; A coupling member integrally installed on the outer circumference of the upper surface of the aeration guide tube, the coupling member having a plurality of coupling holes coupled to and supported by the coupling member to correspond to the coupling holes of the support; Stirring induction pipe which is formed integrally with the lower portion of the aeration induction pipe but is made in the form of a fallopian tube that gradually expands toward the lower portion when stirring the wastewater on the microbial reactor; And protruding formed in a predetermined size on both sides of the aeration induction pipe, each of which may be made of a protruding coupling piece formed in the screw coupling hole up and down. At this time, it is formed integrally with the lower end of the stirring induction pipe but is extended downward to an angle of 120 to 160 degrees waste water agitation angle determination piece for determining the agitation angle of the waste water when stirring the waste water may be further configured.

On the other hand, the configuration of the present invention as described above is provided on the outer circumferential surface of the wastewater induction pipe further comprises a surface vibration preventing means for preventing the phenomenon of the surface of the wastewater generated during aeration and stirring of the wastewater by the forward and reverse rotation of the impeller Can be. At this time, the surface vibration preventing means is a screw member corresponding to the screw coupling hole of the protruding coupling piece is extended to a predetermined length so as to be opposite to both ends of each of the band member and the band member consisting of a pair of semi-circular shape corresponding to the outer diameter of the aeration induction pipe An inner coupling member formed of a connection piece having a ball; Fastening means inserted into the screw coupling hole formed on the connection piece of the inner coupling member and the screw coupling hole of the protruding coupling piece to fix the inner coupling member to the outer diameter of the aeration guide tube; And a vertical surface vibration preventing plate coupled to the inner circumferential surface of the inner coupling member between the connecting member of the inner coupling member and the upper and lower fastening means for coupling and fixing the protruding coupling member to prevent aeration and waste vibration of the wastewater during the forward and reverse driving of the impeller. Can be made.

In addition, the aforementioned vertical surface vibration preventing plate is formed with a semicircular coupling groove corresponding to the outer circumferential surface of the inner coupling member, respectively, and a cutout groove corresponding to the combined thickness of the connecting piece and the protruding coupling piece of the inner coupling member is formed to form a flat plate of the semicircle. A pair of semicircular plates composed of phases; Inner surfaces, which are opposite surfaces of the semi-circle, are bent downwardly, and each of the coupling pieces has a plurality of coupling grooves therethrough; And a coupling means inserted into and coupled to the coupling groove of the coupling piece to fasten and couple the pair of semi-circle plates on the outer circumferential surface of the inner coupling member between the coupling member of the inner coupling member and the upper and lower coupling means for fixing the protrusion coupling piece.

In addition, in the configuration of the present invention, the vertical surface vibration preventing plate of the surface vibration preventing means is installed vertically vertically up and down, but is installed at regular intervals in the horizontal horizontal vibration to prevent the wastewater on the microbial reactor in the horizontal direction The prevention plate may be further provided.

According to the present invention configured as described above through the one watering device equipped with the watering drive motor, the impeller, the watering pipe and the watering induction pipe to supply oxygen according to the agitation and aerobic reaction treatment of sewage and wastewater during sewage and wastewater treatment By allowing the aeration to be selectively performed, the effect of allowing the aerobic reaction of the microorganism to be made smoothly is expressed.

Another effect of the technology according to the present invention is the oxygen according to the agitation and aerobic reaction treatment of sewage and wastewater during the sewage and wastewater treatment through a watering device equipped with a watering drive motor, an impeller, a watering pipe and a watering induction pipe. By allowing the aeration to be supplied selectively, the facilities for agitation and aeration of sewage and wastewater can be simplified to reduce the cost of facilities of sewage and wastewater treatment plants.

In addition, the technology according to the present invention is to supply oxygen according to the agitation and aerobic reaction treatment of sewage and wastewater through a watering device equipped with a watering drive motor, an impeller, a watering pipe and a watering induction pipe. By allowing the aeration to be selectively performed, not only can respond to a wide range of reaction tank, but also prevents the phenomenon that the surface of the waste water flows up and down during aeration or agitation of the waste water.

Hereinafter will be described in detail for the sewage treatment system for sewage and wastewater according to an embodiment of the present invention.

1 is an exploded perspective view showing a sewage treatment device for sewage and wastewater treatment according to the present invention, FIG. 2 is a combined front view showing a water treatment device for sewage and wastewater treatment according to the present invention, and FIG. 3A shows a sewage and wastewater treatment treatment according to the present invention. 3B is a plan view showing the sprinkling plate of the sprinkler for water, FIG. 3B is a plan view showing another sprinkling plate of the sprinkler for sewage and wastewater treatment according to the present invention, FIG. 4B is a cross-sectional view of Figure 4A, Figure 5 is a front sectional view showing the coupling of the impeller and the water pipe according to the present invention, Figure 6A is a sewage and wastewater treatment according to the present invention Figure 6b is a plan view showing the surface vibration preventing plate of the water spray device for water, Figure 6c is a side view of Figure 6a, Figure 7a is a surface vibration jangge wing of the spraying device for sewage and wastewater treatment according to the present invention 7B is a front configuration view shown in FIG. Bottom perspective view of a state in which the surface of the sewage treatment device for the sewage and sewage treatment according to the present invention is installed, FIG. 8A is a front configuration view showing an inner pipe of the water and sewage treatment system for wastewater treatment according to the present invention, and FIG. 9 is a cross-sectional configuration view showing a watering induction pipe of the sewage treatment system for sewage and wastewater according to the present invention.

As shown in Figures 1 to 9, the sewage treatment apparatus 100 for sewage and wastewater treatment according to the present invention is configured in the lower portion of the watering drive motor 110, the watering drive motor 110 is configured to be forward and reverse rotation on the structure Connected to the motor shaft of the housing means, the sprinkling driving motor 110 to be fixed to the installation by pulling the wastewater inside the microbial reaction tank 10 upward through forward and reverse rotation to make aeration or discharge the wastewater downward The impeller 130 and the impeller 130 which stir to make contact with the organic matter and microorganisms contained in the waste water are configured to penetrate the center thereof, which is installed at the lower portion of the housing means, and is pulled upward by the impeller 130. Watering means for spraying the waste water at an angle to make aeration, the coupling is fixedly coupled to the upper side on the impeller shaft 132, but installed between the watering means upward Impeller is located inside the sprinkler tube shape is fixed to the lower triangular sprinkling induction cone 150 and the sprinkling means is extended to a lower portion from the predetermined portion to guide the drawn waste water rotated at a predetermined angle ( It consists of a configuration including a wastewater induction pipe 160 to guide the wastewater upward or downward by the forward and reverse rotation of 130).

In the sprinkling apparatus 100 according to the present invention configured as described above, when the forward and reverse driving of the sprinkler driving motor 110 is performed by the application of a power source, the wastewater inside the microbial reactor 10 by the forward rotation of the impeller 130 is impeller. Pulled upwards through the wastewater induction pipe 160 by the 130 to be sprayed at a predetermined inclination angle through the sprinkling means and the sprinkling induction cone 150 to allow aeration of the wastewater, or reverse rotation of the impeller 130. By discharging the wastewater in the wastewater induction pipe 160 downward to be stirred so that the contact of organic matter and microorganisms contained in the wastewater can be more smoothly contacted.

As described above, the sprinkling apparatus 100 according to the present invention pulls up the wastewater inside the microbial reactor 10 by upward and reverse rotation of the impeller 130 through the forward and reverse driving of the sprinkling driving motor 110 and upwards to the surface of the wastewater. By sprinkling and aeration to create an environment in which microorganisms can grow, as well as to discharge the wastewater in the wastewater induction pipe 160 downward to allow the wastewater to be agitated, the contact between the microorganisms and the organic matter contained in the wastewater is prevented. Make it more smooth. This is achieved by selectively forward and reverse rotation of the watering drive motor (110).

Referring to the configuration of the sewage treatment device 100 for sewage and wastewater treatment according to the present invention in more detail as follows. First, the sprinkling driving motor 110 is driven forward and backward driving the impeller 130 by the application of power to raise the wastewater upwards to make aeration through the spraying or to discharge the wastewater downward to allow the agitation of the wastewater to be made For this purpose, the sprinkling drive motor 110 constitutes the uppermost part of the sprinkling apparatus 100 according to the present invention as shown in Figs. At this time, the sprinkling driving motor 110 is selectively reversed.

On the other hand, the housing means constituting the sprinkling apparatus 100 according to the present invention supports the sprinkling means to be described later to the lower, while installing the sprinkling apparatus 100 according to the present invention on the structure of the microbial reaction tank 10 This housing means is to be fixed, the housing means is formed in the shape of a disk as shown in Figure 1 and 2, but a plurality of coupling grooves (120a) are formed at a predetermined interval fixed installation in the lower portion of the sprinkling drive motor 110 The disk-shaped fixing member 120, which is formed in a cylindrical shape so that the impeller 130 penetrates, the housing body 122 is formed in a predetermined length of the upper and lower, a plurality corresponding to the coupling groove (120a) of the fixing member 120 The coupling groove 124a is formed, but the upper connection piece 124 is integrally formed on the upper edge of the housing body 122 and is integrally configured on the lower edge of the housing body 122 to connect the watering means To support It consists of a lower connection piece 126 is formed a coupling groove 126a of a predetermined interval.

The housing means according to the present invention configured as described above, the upper connecting piece 124 configured on the upper portion of the housing body 122 to the fixed member 120 installed fixed to the lower side of the watering drive motor 110 fastening member 128 By being fixed through) is installed on the lower side of the spraying drive motor (110). At this time, the fixing member 120 and the upper connection piece 124 is coupled and sprinkled through the fastening member 128 inserted into the coupling grooves 120a and 124a in a state where the coupling grooves 120a and 124a of the mutual match. The housing main body 122 is supported on the lower side of the drive motor 110. At this time, the fastening member 128 may be composed of a bolt and a nut.

And, in the housing means of the present invention configured as described above, the upper connecting piece 124 is integrally formed on the upper connecting piece 124, but the sewage treatment device 100 for sewage and wastewater treatment on the structure of the microbial reactor 10 The fixing grooves 124b-1 for fixing to the plurality of fixing pieces 124b formed at each end are further configured. That is, the fixing piece 124b is the upper structure of the sprinkling apparatus 100 when the sprinkling apparatus 100 is installed on the upper structure 12 configured on the top of the microbial reactor 10 as shown in FIGS. 10 to 13. The fixing bolt (not shown) on the (12) is to function to.

In other words, as described above, the fixing piece 124b integrally formed on the upper connection piece 124 is inserted through the fixing grooves 124b-1 formed in each of the upper structures 12 of the microbial reactor 10. The sprinkling device 100 according to the present invention is fixed through a fixing bolt (not shown) fastened onto the upper structure 12 of the microbial reactor 10.

Impeller 130 constituting the sprinkling apparatus 100 according to the present invention is aerated by pulling up the wastewater inside the microbial reaction tank 10 through the forward and reverse rotation to make aeration or downward to make the agitation of the wastewater This impeller 130 is to be forward and reverse rotation by the forward and reverse driving of the spraying motor 110 is connected to the upper portion on the motor shaft of the spraying motor 110 as shown in Figure 1 and 5 It is done.

The impeller 130 configured as described above is a screw-shaped blade 134 is formed in a double or triple on the shaft of a predetermined length as shown in Figures 1, 2 and 5, but the impeller shaft 132 On the outer peripheral surface of the upper side of the screw groove 136 is formed of a structure formed. The impeller 130 formed as described above is coupled to the motor shaft of the sprinkling driving motor 110 through the coupling 170 coupled to the upper portion.

As described above, the coupling 170 coupling the impeller 130 on the motor shaft of the sprinkling driving motor 110 may include a motor shaft coupling part 172 and an impeller coupled to the motor shaft of the sprinkling driving motor 110. Impeller coupling portion 174 and impeller coupling portion in which screw holes 174b are formed at both sides of the coupling hole 174a having a diameter corresponding to the shaft 132 and the screw groove 136 of the impeller shaft 132. 174 is formed on the lower outer periphery of the coupling hole 176a is formed at a predetermined interval is formed in the upper surface of the sprinkling guide cone 150 is coupled to the impeller 130 and the fastening member ( 158 is made of an induction cone coupling portion 176 coupled through. At this time, the fastening member 158 may be made of a bolt and a nut.

The above-described coupling 170 is a screw groove 136 and the impeller coupling portion 174 of the impeller shaft 132 in a state where the upper end of the impeller shaft 132 is inserted through the coupling hole 174a of the impeller coupling portion 174. After coupling the fastening member 178 with the screw groove 136 of the impeller shaft 132 and the screw hole 174b of the impeller coupling portion 174 by matching the screw holes 174b of The impeller 130 is coupled to the sprinkling driving motor 110 by engaging on the motor shaft of the sprinkling driving motor 110 through the motor shaft coupling part 172 forming the upper end of the 170. At this time, the fastening member 178 may be made of a bolt and a nut.

On the other hand, as described above, before coupling and fixing the impeller 130 to the coupling 170, the sprinkling induction cone 150, which will be described later, is first coupled to the outer peripheral surface of the shaft 132 of the impeller 130, and then the coupling 170 ) And fixed to the impeller (130). At this time, the induction cone coupling portion 176 constituting the lower portion of the coupling 170 is fastened with the coupling hole 154a formed on the upper surface of the sprinkling induction cone 150 through the coupling hole 176a formed at a predetermined interval. Is coupled through member 158.

The sprinkling means constituting the present invention is for sprinkling the wastewater pulled upward by the forward rotation of the impeller 130, the sprinkling means is of the form that is reduced to the bottom in the center as shown in Figs. The spraying through hole 140a is formed, but the support 140 having a predetermined thickness and a plurality of coupling holes 140b are formed on the lower surface around the spraying through hole 140a at a predetermined interval. Is installed at intervals, but the sprinkling plate 142, the support 140 and the sprinkling plate 142 to be discharged at a predetermined angle so that the waste water pulled upward by the impeller 130 is installed at regular intervals to the support ( 140 is configured of the spacer 144 to maintain the spacing of the spacing plate 142 and the fastening member 146 through the support 140 and the spacing retainer 144 and the sprinkling plate 142 through the coupling Is done.

The sprinkling means configured as described above is fixed through the fastening member 146 in a state in which the support 140 and the sprinkling plate 142 are maintained at regular intervals up and down through the plurality of gap holders 144, and then the sprinkling plate 142 and the matching coupling groove 142c of the lower connecting piece 126 and the coupling through the coupling member 148 inserted into the coupling hole 126a is coupled to be supported by the lower portion of the housing body 122. At this time, the coupling member 148 may be made of a bolt and a nut.

On the other hand, as described above, the sprinkling means coupled to the lower portion of the housing main body 122 through the sprinkling of the support 140 through the wastewater flowing through the interior of the wastewater induction pipe 160 to be described later by the forward rotation of the impeller 130 The waste water is sprinkled onto the water through the ball 140a. At this time, the waste water to be sprayed onto the water is sprayed at a predetermined inclination angle through the inclination angle of the spraying guide cone 150 to be described later.

In the sprinkling means of the present invention as described above, the sprinkling plate 142 has a plurality of coupling holes 142d corresponding to the coupling holes 126a of the lower connection piece 126, as shown in FIG. A plate body 142a on a plate that is coupled to and supported by a lower portion of the housing body 122 through the shaft, a shaft through hole 142b formed to penetrate through a predetermined diameter so that the impeller shaft 132 penetrates through the center of the plate body 142a, and It may be made of a configuration of the wastewater scattering groove 142c formed incision on the outer periphery of the plate body 142a at a predetermined interval so that the wastewater drawn up by the impeller 130 is ejected and scattered at a predetermined angle.

The sprinkling plate 142 configured as described above is guided upward by the inclined surface of the sprinkling guide cone 150 that rotates with the impeller 130 and the wastewater pulled upward by the impeller 130 is the sprinkling plate 142. In addition to scattering the wastewater hitting the lower surface of the), the wastewater induced upwards is sprayed at a predetermined angle through the wastewater scattering groove 142c of the sprinkling plate 142 so that the aeration of the wastewater is made.

In addition, the sprinkling plate 242 of another example in the sprinkling means according to the present invention is formed with a plurality of coupling holes 242d corresponding to the coupling hole 126a of the lower connection piece 126, as shown in Figure 3b coupling member 148 Plate body 242a on the plate coupled and supported by the housing body 122 through the lower portion, the shaft through-hole 242b and plate formed to penetrate through a predetermined diameter so that the impeller shaft 132 penetrates to the center of the plate body 242a The through hole 242b of the main body 242a is formed on the outer circumference at a predetermined interval so that the wastewater drawn up by the impeller 130 is made of a configuration of the discharge hole 242c to be discharged upward.

Another example of the watering plate 242 configured as described above is a watering plate is directed upward by the inclined surface of the watering induction cone 150 rotates with the impeller 130, the wastewater pulled upward by the impeller 130 The wastewater that strikes the lower surface of 242 is to be scattered, as well as the wastewater induced upwards to be sprayed through the jet hole 242c of the sprinkling plate 242 so that the waste water aeration.

The watering induction cone 150 constituting the present invention is located between the support 140 and the watering plate 142 is pulled upward through the watering through hole 140a of the support 140 by the forward rotation of the impeller 130 In order to spray the raised wastewater to a certain inclination angle, this watering induction cone 150 is a shaft hole through which the impeller shaft 132 is coupled through the center as shown in Figs. 152, the coupling coupling portion 154 and the coupling coupling member 154 formed with a plurality of coupling holes 154a corresponding to the coupling holes 176a formed in the induction cone coupling portion 176 of the coupling 170. It is formed integrally at the bottom but is formed in the shape of a cone that gradually decreases in diameter toward the bottom, the wastewater drawn up upward through the sprinkling through hole (140a) of the supporter 140 through the outer peripheral surface guided spraying It is made of a sprinkling cone (156).

The sprinkling guide cone 150 configured as described above is inserted and coupled to the upper side of the impeller shaft 132 through the shaft hole 152 through the coupling hole 154a formed in the coupling coupling portion 154 (induction cone coupling portion ( 176). At this time, the adhesive is applied to the inner circumferential surface of the shaft hole 152 of the watering induction cone 150 is bonded to the outer circumferential surface of the impeller shaft 132. Applying the adhesive as described above is to further reinforce the bonding force of the sprinkler guide cone 150 and the impeller 130.

On the other hand, since the shape of the sprinkling cone 156 of the sprinkling induction cone 150 configured as described above is formed in a cone shape that gradually decreases in diameter toward the bottom of the wastewater induction pipe 160 as described above Wastewater that is introduced through the spraying through hole 140a of the supporter 140 is sprinkled by being guided at a predetermined inclination angle through the inclined surface of the spraying cone 156. At this time, since the sprinkling guide cone 150 is fixed to the impeller 130, the sprinkling water is rotated in the rotational direction of the impeller 130 and pulled upward.

As described above, when the sprinkling water is pulled upward through the sprinkling induction cone 150, the sprinkling water that is sprinkled onto the surface of the water is widely sprinkled. At this time, since the waste water contains microorganisms, air bubbles are formed by contact with oxygen in the air and impacted water drops fall on the water surface to supply oxygen to the wastewater inside the microbial reactor 10. As such, it creates aerobic conditions for microorganisms to grow inside the microbial reactor (10) through the waste water.

The sprinkling induction cone 150 configured as described above is located in the center between the support 140 and the sprinkling plate 142 as shown in FIGS. 1 and 2, and a lower portion thereof is a sprinkling through-hole of the support 140. The wastewater guided by being inserted on the 140a but guided upward through the outer circumferential surface of the sprinkling guide cone 150 is inserted to be spaced apart from the inner circumferential surface of the sprinkling through-hole 140a by a predetermined interval upward. Spraying is allowed to splash in the middle of hitting on the bottom surface of the tweezers 142. That is, the lower portion of the spraying guide cone 150 is inserted on the spraying through hole 140a of the supporter 140, but is spaced apart from the inner circumferential surface of the spraying through hole 140a by being spaced apart at a predetermined interval. The wastewater is pulled upward through the sprayed water guided by the sprinkler guide cone 150.

The wastewater induction pipe 160 constituting the present invention is to induce wastewater when the wastewater due to the forward and reverse rotation of the impeller 130 is pulled upward or discharged downward, and the wastewater induction pipe 160 is illustrated in FIG. As shown in Figure 2 and 9 coupled to the lower portion of the sprinkling means is made of a fallopian tube shape that extends from the predetermined portion to the lower portion of the wastewater by the forward and reverse rotation of the impeller 130 located therein Will lead to.

On the other hand, when the wastewater induction pipe 160 as described above in more detail, the aeration induction pipe 162, aeration induction pipe 162 of a predetermined size for inducing wastewater on the microbial reactor 10 through the inside of the Coupling member 164, which is installed integrally on the outer circumferential surface of the upper surface and formed with a plurality of coupling holes 164a that are supported by coupling means 164b corresponding to the coupling holes 140a of the supporter 140, inducing aeration When the agitation of wastewater on the microbial reactor 10 is made of a form of a fallopian tube that is integrally formed in the lower portion of the pipe 162 and gradually expands downward, the stirring induction pipe 166 and the aeration induction pipe 162 which induce the waste water to be stirred. Protrudingly formed on both sides of the) to a predetermined size, each of which consists of a protruding coupling piece 168 is formed with a screw coupling hole (168a) up and down.

The wastewater induction pipe 160 configured as described above is installed in a state submerged in the wastewater of the microbial reactor 10 so that the wastewater inside the wastewater induction pipe 160 during aeration due to the forward rotation of the impeller 130 is aeration induction pipe 162. While inducing upward through the), when the stirring due to the reverse rotation of the impeller 130 guides the wastewater inside the wastewater induction pipe 160 to the stirring induction pipe 166 to allow the agitation of the wastewater.

In addition, the wastewater agitator which is formed integrally with the lower end of the stirring induction pipe 166 of the wastewater induction pipe 160 configured as described above and extends downward at an angle of 120 to 160 degrees to determine the stirring angle of the wastewater when the wastewater is stirred. The angle determination piece 166a is further comprised. The wastewater stirring angle determination piece 166a thus formed determines the stirring angle of the wastewater discharged downward as shown in FIGS. 12 and 13 when the wastewater is stirred. At this time, the waste water agitating angle determination piece 166a is designed at an angle of 120 to 160 degrees depending on the size of the microorganism reactor 10 or other conditions.

The sprinkling apparatus 100 according to the present invention configured as described above is installed on the outer circumferential surface of the wastewater induction pipe 160 to relieve the phenomenon of wastewater surface generated during aeration and stirring of the wastewater by the forward and reverse rotation of the impeller 130. Sleep vibration preventing means is further configured. At this time, the surface vibration prevention means is a band member 180a and a band member (180a) formed of a pair of semi-circular shapes corresponding to the outer diameter of the aeration induction pipe 162, as shown in Figures 1, 2 and 6 to 8 ( An inner coupling member consisting of a connection piece 180b having a screw coupling hole 180b-1 corresponding to the screw coupling hole 168a of the protruding coupling piece 168 and extending a predetermined length so as to face each other at both ends. 180), the inner coupling member 180 is inserted and coupled through the screw coupling hole 180b-1 formed on the screw coupling hole 168a of the protruding coupling piece 168 and the connection piece 180b of the inner coupling member 180. The inner coupling between the fastening means 182 fixing the aeration guide pipe 162 to the outer diameter and the upper and lower fastening means 182 coupling and fixing the connection piece 180b of the inner coupling member 180 and the protruding coupling piece 168. The member 180 is coupled on the outer circumferential surface of the wastewater during the forward and backward driving of the impeller 130 and the phase of the wastewater during stirring It consists of a vertical surface the anti-vibration plate 184 to prevent the vibration.

Meanwhile, as described above, the vertical surface vibration preventing plate 184 is formed with a semicircular coupling groove 184a-1 corresponding to the outer circumferential surface of the inner coupling member 180, while the connecting piece 180b of the inner coupling member 180 is formed. ) And a cutout groove 184a-2 corresponding to the combined thickness of the protruding coupling pieces 168 are formed to form a pair of semicircle plates 184a and semicircle plates 184a formed on a flat plate of a semicircle. The inner surface is bent downward, each of which is coupled to the coupling piece 184b and the coupling groove 184b-1 of the coupling piece 184b through which a plurality of coupling grooves 184b-1 are formed. Fastening means for coupling the semi-circular plate 184a on the outer peripheral surface of the inner coupling member 180 between the connecting piece 180b of the inner coupling member 180 and the upper and lower fastening means 182 to which the protrusion coupling piece 168 is fixed. 184c).

The above-described surface vibration preventing means is coupled on the outer circumferential surface of the inner coupling member 180 to prevent the surface of the wastewater flowing up and down during aeration and stirring. That is, when the surface of the wastewater flows up and down during the aeration and agitation of the wastewater, the flowing wastewater is hit by the vertical surface vibration preventing plate 184 constituting the surface vibration preventing means and the flow is gradually lost. As a result, the surface vibration preventing means prevents the surface of the wastewater from flowing up and down during aeration and agitation of the wastewater.

In addition, the bottom surface of the vertical surface vibration preventing plate 184 of the water surface vibration preventing means of the sprinkler according to the present invention is installed vertically vertically at regular intervals in the waste water on the microbial reaction tank 10 in the horizontal direction Horizontal sleep vibration preventing plate 190 is further provided to prevent the vibration.

The vertical surface vibration preventing plate 184 and the horizontal surface vibration preventing plate 190 of the surface vibration preventing means configured as described above have the water surface of the waste water during aeration and agitation due to the forward and reverse rotation of the impeller 130. Preventing the flow in the horizontal direction prevents the occurrence of abnormality by preventing the vibration of the watering device 100 according to the present invention by the waste water flowing.

10 is a front configuration diagram showing an open type installation during aeration of the sewage treatment system for sewage and wastewater treatment according to the present invention, and FIG. 11 is a front configuration diagram showing a closed type installation during aeration of the sewage treatment system for sewage treatment equipment according to the present invention; 12 is a front configuration diagram showing an open type installation of the sewage treatment system for sewage and wastewater treatment according to the present invention, and FIG. 13 is a front configuration diagram showing a closed type installation for stirring of the sewage treatment system for sewage and wastewater treatment according to the present invention. .

10 to 13, the sprinkling apparatus 100 according to the present invention can be installed in any of the structure of the open top and closed structure of the microbial reaction tank (10). That is, in the case of the microorganism reactor 10 having an open structure as shown in FIGS. 10 and 12, after the upper structure 12 is installed on the open microbial reactor 10, the upper structure 12 is disposed on the upper structure 12. It is fixed through the upper connecting piece (124). At this time, the watering means is installed in the state exposed to the surface of the wastewater, wastewater induction pipe 160 including the sleep vibration prevention means is installed in a state of being submerged in the wastewater.

Meanwhile, in the case of the microbial reactor 10 of the closed string structure as shown in FIGS. 11 and 13, the same method as in FIGS. 10 and 12 is performed on the upper structure 12 that forms the ceiling of the microbial reactor 10. Install a watering device according to the invention.

The technology according to the present invention is not limited to the above-described embodiments and can be carried out in various modifications without departing from the technical spirit of the present invention.

1 is an exploded perspective view showing a water treatment device for sewage and wastewater treatment according to the present invention.

Figure 2 is a combined front view showing the water treatment device for sewage and wastewater treatment in accordance with the present invention.

Figure 3a is a plan view showing a sprinkling plate of the sewage treatment device for sewage and wastewater in accordance with the present invention.

Figure 3b is a plan view showing another watering plate of the water treatment device for sewage and wastewater treatment according to the present invention.

Figure 4a is a perspective configuration showing the water pipe of the sewage treatment device for sewage treatment according to the present invention.

4B is a cross-sectional view of FIG. 4A.

Figure 5 is a front cross-sectional view showing the coupling of the impeller and the spray pipe according to the present invention.

Figure 6a is a front configuration diagram showing the surface vibration preventing plate of the sewage treatment device for sewage and wastewater in accordance with the present invention.

6B is a plan view of FIG. 6A.

6C is a side view of FIG. 6A.

Figure 7a is a front configuration diagram showing the surface of the vibration oscillating wing of the water treatment device for sewage and wastewater treatment according to the present invention.

Figure 7b is a bottom perspective view of the state installed the surface vibration jangji wing of the water treatment device for sewage and wastewater treatment according to the present invention.

Figure 8a is a front configuration diagram showing the inner pipe of the sewage treatment system for sewage and wastewater in accordance with the present invention.

8B is a plan view of FIG. 8A.

Figure 9 is a cross-sectional view showing the watering induction pipe of the sewage treatment device for sewage and wastewater in accordance with the present invention.

10 is a front configuration diagram showing an open type installation during aeration of the sewage treatment system for sewage and wastewater according to the present invention.

11 is a front configuration diagram showing a sealed installation during aeration of the sewage treatment system for sewage and wastewater according to the present invention.

Figure 12 is a front configuration diagram showing an open type when stirring the sewage treatment device for sewage treatment according to the present invention.

Figure 13 is a front configuration diagram showing a sealed installation when stirring the sewage treatment device for sewage treatment according to the present invention.

[Description of Symbols for Main Parts of Drawing]

100. Spraying device 110. Spraying motor

120. Retaining member 122. Housing body

124. Upper connection piece 126. Lower connection piece

130. Impeller 140. Support

142. Watering Plate 144. Spacer

146. Fastening means 150. Sprinkler guide cone

152. Shaft hole 154. Coupling coupling

156. Salcon cone 160. Wastewater induction pipe

162. Aeration Induction Tube 166. Agitating Induction Tube

170. Coupling 172. Motor Shaft Coupling

174. Impeller coupling 176. Induction cone coupling

180. Inner coupling member 184. Vertical surface vibration preventing plate

190. Horizontal surface vibration damper

Claims (16)

A watering and driving motor configured to be capable of forward and reverse rotation to supply oxygen to the wastewater inside the microbial reactor so that the wastewater can be purified by the microbial reaction under aerobic conditions; A housing means configured at a lower portion of the sprinkler driving motor to allow installation and fixing on the structure; It is connected to the motor shaft of the watering drive motor to pull up the wastewater inside the microbial reactor through the forward and reverse rotation to aeration or to send the wastewater downward to agitate so that the organic matter contained in the wastewater is in contact with the microorganisms. Impeller; A watering means configured to penetrate the center of the impeller so as to be installed at a lower portion of the housing means to sprinkle the wastewater pulled upward by the impeller at a predetermined angle so that aeration occurs; A sprinkling induction cone having an inverted triangular shape coupled to the upper side of the impeller shaft and installed between the sprinkling means to guide the wastewater pulled upward at a predetermined angle while being rotated at the same rotational speed as the impeller; And a wastewater induction pipe that is fixedly coupled to a lower portion of the watering means and is formed in a fallopian tube shape that extends from a predetermined portion toward a lower portion to guide the wastewater upward or downward by forward and reverse rotation of the impeller located therein. In the sprinkling device for sewage and wastewater treatment, On the outer circumferential surface of the wastewater induction pipe is a surface vibration preventing means for preventing the phenomena of the surface of the wastewater caused by aeration or agitation of the wastewater by the forward and reverse rotation of the impeller is further provided, the surface vibration preventing means, Protruding coupling pieces protruding to a predetermined size on both sides of the wastewater induction pipe while the screw coupling hole is formed up and down; A connection piece having a semi-circular pair of band members corresponding to the outer diameter of the wastewater induction pipe and a screw coupling hole corresponding to a screw coupling hole of the protruding coupling piece, while extending a predetermined length to face opposite sides of each of the band members. Inner coupling member is fixed to the protruding coupling piece through a fastening means; Vertically installed on the inner circumferential surface of the inner coupling member between the connecting member of the inner coupling member and the upper and lower fastening means for coupling and fixing the protruding coupling member to prevent the aeration or waste vibration of the wastewater during agitating and driving the impeller. Sleep vibration prevention plate; And A horizontal sleep vibration preventing plate installed at a predetermined angle interval in a vertical manner vertically on a lower surface of the vertical sleep vibration preventing plate to prevent the wastewater on the microbial reaction tank from vibrating in the horizontal direction; Sewage treatment device for sewage and wastewater, characterized in that configured to include. According to claim 1, wherein the vertical surface vibration preventing plate, A pair of semi-circle plates formed with semi-circular plates formed on the outer circumferential surface of the inner coupling member, respectively, while cutting grooves corresponding to the combined thicknesses of the connecting piece and the protruding coupling piece of the inner coupling member are formed. ; Inner surfaces of the semi-circular plate are formed to be bent downward to each other, each of the coupling pieces are formed through a plurality of coupling grooves; And A fastening means inserted into and coupled to the coupling groove of the coupling piece to fasten the pair of semi-circle plates on the outer circumferential surface of the inner coupling member between the coupling means of the inner coupling member and the upper and lower fastening means for coupling and fixing the protrusion coupling piece; Sewage treatment device for sewage and wastewater, characterized in that consisting of. The method of claim 2, wherein the housing means, A disk-shaped fixing member which is formed in a disk shape but has a plurality of coupling grooves formed at predetermined intervals and is fixedly installed in the lower portion of the sprinkler driving motor; A housing main body which is formed in a cylindrical shape so that the impeller penetrates and is formed to have a predetermined length above and below; An upper connection piece having a plurality of coupling grooves corresponding to the coupling grooves of the fixing member and integrally formed on the upper edge of the housing body; And A lower connection piece which is integrally formed on the lower edge of the housing main body and has a coupling groove at a predetermined interval for connecting and supporting the watering means; Sewage treatment device for sewage and wastewater, characterized in that consisting of. The method of claim 2, wherein the impeller is a screw-shaped blade is formed on the shaft of a predetermined length in a double or triple, the screw groove is formed on the outer peripheral surface of the upper side of the impeller shaft for sewage and wastewater treatment, characterized in that Sprinkler. According to claim 4, The impeller is coupled to the motor shaft of the sprinkling drive motor through the coupling, The coupling is coupled to the motor shaft of the sprinkling drive motor; An impeller coupling portion having screw holes formed at both sides corresponding to a coupling hole having a diameter corresponding to the impeller shaft and a screw groove formed at the impeller shaft; And The impeller coupling portion is formed on the lower outer periphery of the sewage, wastewater treatment characterized in that the coupling hole is formed at a predetermined interval formed by the induction cone coupling portion coupled to the upper surface of the sprinkler guide cone coupled to the impeller through a fastening means Watering device. According to claim 5, The sprinkling means has a sprinkling through-hole of the form that is reduced to the lower portion in the central portion of the support having a predetermined thickness formed at a predetermined interval on the lower surface around the sprinkling through-hole; A sprinkling plate which is installed at a predetermined interval on an upper portion of the support but allows the wastewater drawn up upward by the impeller to be sprinkled at a predetermined angle; A gap holder installed at an edge of the support and the sprinkling plate to maintain a gap between the support and the sprinkling plate; And Sewage treatment device for sewage and wastewater, characterized in that consisting of a fastening means for fastening and coupling through the support and the spacing support and the sprinkling plate. The plate body of claim 6, wherein the watering plate comprises: a plate body on which a plurality of coupling holes corresponding to the coupling holes of the lower connection piece are formed and coupled to and supported by the housing body under the coupling member; A shaft through-hole formed through a predetermined diameter so that the shaft of the impeller penetrates the center of the plate body; And Sewage treatment device for sewage and wastewater treatment, characterized in that formed on the outer periphery of the plate body at a predetermined interval so that the wastewater pulled up by the impeller is discharged at a predetermined angle to scatter. The plate body of claim 6, wherein the watering plate comprises: a plate body on which a plurality of coupling holes corresponding to the coupling holes of the lower connection piece are formed and coupled to and supported by the housing body under the coupling member; A shaft through-hole formed through a predetermined diameter so that the shaft of the impeller penetrates the center of the plate body; And Sewage treatment device for sewage and wastewater treatment, characterized in that the through-hole formed in a predetermined interval on the outer periphery of the axial through-holes of the plate body so that the wastewater drawn up by the impeller is discharged upward. According to claim 7 or 8, The sprinkling induction cone is a shaft hole through which the impeller shaft is coupled through the center; A coupling coupling portion in which a plurality of coupling holes corresponding to the coupling holes formed in the induction cone coupling portion of the coupling are formed; And It is formed integrally at the lower portion of the coupling coupling member but formed in the shape of a cone whose diameter gradually decreases toward the lower portion, the wastewater drawn upwardly through the sprinkling through hole of the support is sprayed at a predetermined inclination angle through its outer peripheral surface. Sewage treatment device for sewage and wastewater, characterized in that consisting of a sprinkler. 10. The method of claim 9, wherein the sprinkling induction cone is positioned in the center between the support and the sprinkling plate, the lower portion is inserted into the sprinkling through-hole of the support but inserted so as to be spaced apart from the inner circumferential surface of the sprinkling through-hole And the wastewater drawn up upwards is guided upwardly through the outer circumferential surface of the sprinkler induction cone so that the sprinkled water is scattered while the guided wastewater collides with the lower surface of the sprinkling plate. Sprinkler for wastewater treatment. 11. The method of claim 10, The wastewater induction pipe is an aeration induction pipe having a predetermined size for inducing wastewater on the microbial reactor through the inside; A coupling member integrally installed on an outer circumference of the upper surface of the aeration guide tube, the coupling member having a plurality of coupling holes coupled to and supported by the coupling member in response to the coupling holes of the support; A stirring induction pipe which is formed integrally with the lower portion of the aeration induction pipe and is formed in a fallopian tube shape that gradually expands toward the lower portion of the aeration induction pipe when stirring the wastewater on the microbial reactor; And Sewage treatment device for sewage and wastewater treatment, characterized in that formed on both sides of the aeration guide pipe in a predetermined size, each of which consists of protruding coupling pieces formed in the screw coupling hole up and down. 12. The method according to claim 11, wherein the lower part of the stirring induction pipe is integrally formed, but extends downward at an angle of 120 to 160 degrees, and further comprises a waste water agitating angle determination piece for determining the agitation angle of the waste water upon stirring the waste water. · Sprinkler for wastewater treatment. delete delete delete delete

Images