KR200235061Y1 - Roter of oxidation ditch - Google Patents

Abstract

This paper is about Guro-Ota oxide, which is widely used as aeration device for oxidizing sphere, which is widely used in small and medium-sized sewage treatment plants. Even though the influent water load frequently appeared in small sewage treatment plants, oxygen transfer capacity and stirring power (mixing power) The purpose of this study is to improve the quality of the treatment water by making it possible to control the condition of the treatment process easily by completely mixing and supplying the appropriate oxygen by controlling it independently. For this purpose, the stirring rotor of the rotary rotor installed in the water of the oxidizing sphere At the end, install the oxidizing sphere rotor and concentric guide ring, and install the height-adjustable scattering guide plate on the water transfer direction of the oxidizing rotor, and arbitrarily adjust the degree to which the water splashing from the oxidizing rotor into the air contacts the air. Mixing and adjusting at the same time In this way, it is possible to freely control the total mixing and oxygen transfer amount necessary to purify the sewage according to the inflow water quality load, thereby maintaining the optimal state in the oxidizing sphere at an optimal state, thereby purifying pollutants. It can increase the efficiency of removing nutrients.

Description

Rotor of oxidation ditch

The purpose of the present invention is to provide oxidizer rotators that can independently control the mixing and oxygen transfer abilities of oxidizers in the oxidizers used in small and medium sized sewage / wastewater treatment plants. Even though the load is low, the oxygen transfer amount can be freely controlled while maintaining the proper dissolved oxygen concentration, and the oxygen transfer amount is reduced in the denitrification process required for removing nutrients such as nitrogen, so that anaerobic sections are easily formed. Is to maximize.

The present invention is a technique for the oxidative sphere rotor for mixing and oxygen transfer of oxidized spheres widely used as bioreactors in sewage and wastewater treatment plants.

Conventionally, the oxidizer sphere rotor used in the oxidizing sphere changes the rotation speed of the oxidizer sphere in order to adjust the amount of oxygen transfer or mixing power (agitating force to completely mix the mixed liquid and inflow / waste water in the oxidizing sphere and prevent sludge settling). Or the depth at which the stirring blades of the oxidative sphere rotor were submerged in water.

However, since this changes in the same tendency when the oxygen transfer amount and the mixing power increases or decreases, the low dissolved oxygen concentration required in the case where the water quality of the sewage or wastewater is low in BOD or in the case where nitrification and denitrification occurs simultaneously in the oxidizing spheres. It was almost impossible to maintain.

In order to achieve an effective treatment in the above cases, it is necessary to maintain low dissolved oxygen concentration and maintain sufficient mixing power. In the conventional oxidation furnace rotor, to reduce the dissolved oxygen concentration, the rotation speed of the oxidation furnace rotor is reduced or Reducing the immersion depth also reduced the mixing power, which prevented the normal oxidative sphere from operating due to precipitation of solids in the mixed liquor or non-uniformity of the MLSS concentration.

The technical problem to be achieved by the present invention is to provide a oxidizer which can independently control the mixing capacity and oxygen transfer capacity of the oxidizer, and the mixing ability is maintained even when the BOD load of the influent sewage / wastewater is low by using the oxidizer. In addition, the oxygen transfer amount is freely controlled to maintain the proper dissolved oxygen concentration and to reduce the oxygen transfer amount in the denitrification process necessary for removing nutrients such as nitrogen, so that anaerobic sections are easily formed, thereby maximizing the denitrification effect and the water treatment effect in the oxidizing sphere.

1 is a plan view showing the configuration of the present invention

Figure 2 is a cross-sectional view A-A showing the configuration of the present proposal

Figure 3 is a detailed view of the scattering water flow control apparatus of the present invention

Explanation of symbols for important parts of the drawings

1. Gurorota body

2. Stirring

3. Guide ring

4. Rota Shaft

5. bearing bearing assembly

6. Rotor drive shaft

7. Drive shaft bearing assembly.

8. Gear Reducer

9. Drive motor

10. Rotational Transmission

11.Rota Cava

12. Cover for beam

13. Shatterproof Covers

14. Kabanur dog

15. Tightening Screw

16. Fugitive Water Control Panel 16-1. Guide post 16-2. rubber Board

16-3. Rubber plate presser 16-4. Rubber Plate Tightening Screw

17. Information Home 17-1. Fixing Bracket 17-2. Upper flange

18. Lifting screw rod

19. Top cover plate 19-1. Cover Plate Tightening Screw

20. Handle 20-1. 4-square key

21. Foundation screw

The length of the oxidizing sphere in the middle of the longitudinal direction of the oxidizing sphere in the oxidizing sphere composed of the external structural wall (A), the bottom (A) and the intermediate bulkhead (B), and having the sewer inlet (C) and the sewer outlet (D). The middle passage (e) perpendicular to the direction is installed horizontally above the structure of the oxidizing sphere, and the guro rotator main body (1) is installed horizontally at right angles to the longitudinal direction of the oxidizing sphere with the middle passage (e) centered thereon. At the outside of 1), the spiral stirring blades 2 are installed at fixed intervals so as to be integrally fixed with the guro-rota body 1 as shown in FIG. 2, and the height of the installation of the oxidation-rota body 1 is in the water. Decide to lock about 200mm. At one end of the guro-rotated main body 1, the rota-shaft 4 was integrally fixed to the guro-rotated main body 1 and the concentric shaft, and the rota-shaft 4 was rotatably supported by the bearing assembly 5.

At the other end of the oxidizing rotor body (1), the rotor drive shaft (6) is firmly installed on the concentric shaft and supported by the drive shaft bearing assembly (7), and the gear reducer (8) is supported at the end of the rotor drive shaft (6). The rotational force of the reduction gear was transmitted to the rotatable drive shaft 6, and the hollow gear reducer 8 was connected to the drive motor 9 through the rotation transmission device 10.

45 ° to 60 ° angle of symmetry between the outer structure wall (a) and the middle partition wall (b) of the oxidizing sphere in the forward direction (water flow direction). The guide groove 17 having a c-shaped guide section may be installed to be inclined to be inclined by the site conditions, and the guide groove 17 may be integrally formed with fixing brackets 17-1 on both sides of the guide groove 17. Here, the position was fixed by the basic screw 21 which drilled the hole for a screw and planted it in the outer wall structure (a) and intermediate | middle bulkhead (b) of an oxidation ball.

In addition, the upper flange 17-2 is integrally formed on the upper side of the guide groove 17 to fix the upper cover plate 19, and the bolt hole is drilled to be fastened with a fixing screw, and the lower side of the guide groove 17 is flat. As a result, the hole was bored so that the bottom of the Sungkang screw rod 18 could be inserted in the center of the plate.

The guide groove (17) has a four-sided section and a scattering flow control plate (16) having a centrally mounted guide column (16-1) integrally formed at both centers with female threads corresponding to the male threads of the elevating screw rod (18) at the center thereof. Insert the guide column (16-1), and then put the elevating screw rod (18) into the screw assembly, and then insert the upper cover plate (19) from the upper side of the elevating screw rod (18) and then the upper cover plate (19) Was fixed by tightening the cover plate tightening screw (19-1) on the upper flange (17-2) of the guide groove.

At the top of the elevating screw rod 18, a handle 20 for rotating the elevating screw rod 18 was inserted and fixed with a quadrilateral key 20-1.

Since the trajectory of the water droplets protruding from the oxidizer sphere is parabolic, similar to the shape of the scattering flow, the scattering flow control plate 16 has a parabolic curve viewed from the side, and the front part of the scattering flow control plate 16 on the stirring blade (2). To prevent contact of the tip of the stirrer blades (2) of the stirrer blade (2) close to the guide ring (3) concentrically installed in order to mitigate the impact in case of contact, a hard rubber plate (16) -2) and the rubber plate presser (16-3) was pressed on the rubber plate (16-2) and then tightened the rubber plate tightening screw (16-4) was fixed to the splash control plate (16).

In addition, in order to prevent scattering of the water flow scattered on the Gurota oxidizer body 1, a rotacarba 11 having an arcuate cross section is installed in contact with an intermediate passage (e), and the other end of the flow control plate 16 It was installed in such a length as not to interfere with the ascent of the elevating, and at the end thereof, a flexible scattering prevention cover 13 was installed to prevent the gap generated during the ascent of the scattering flow control plate 16.

One oxidizing sphere rotor of the above structure was installed in each channel so as to be symmetrical to the intermediate passage (e).

The function of Guro Rota formed in this way is as follows.

First, adjust the rotation speed of the oxidizing sphere rotor so that the mixing power of the oxidizing sphere rotor is required or adjust the depth in which the stirring blade 2 is submerged in water.

Oxygen transfer to the water in the oxidizer rotor is caused by the rotation of the oxidizer rotor and the water, which has been centrifugal at the stirring blade (2), springs up into the air and falls back into the air, while the water droplets come into contact with the air while the water droplets contact the air It is achieved by absorbing and moving into water.

Therefore, if left in the natural state, the height of water splashing out of the oxidizer sphere is maximized, and the time of contact with air and the amount of water droplets are maximized, thereby increasing the amount of oxygen transfer into the water.

Therefore, it is clear that the amount of oxygen transfer is reduced by preventing the water droplets bouncing from the oxidizing sphere rotor from being bouncing high by appropriate means.

In this case, the guide column 16-1 is moved up and down by the screw action of the elevating screw rod 18 by turning left and right the handle 20 assembled integrally at the end of the elevating screw rod installed in the guide groove 17. Since it can move freely, the scattering flow control plate 16, which is fixed here, also moves up and down together, so when a large amount of oxygen transfer is required, raise the position of the scattering flow control plate 16 to the maximum, and the water droplets that protrude from the rotor When the small amount of oxygen transfer is required, the water droplets protruding from the oxidizing sphere by lowering the scattering flow control plate 16 can be suppressed, thereby reducing the contact time between the water droplets and the air and reducing the amount of oxygen transfer.

However, when the splash control plate 16 is at a high position or at a low position, the water splashing out of the guro-oxide is suppressed only at the height of the splash, and the inherent energy of the splash control plate having a parabolic cross section ( 16) flows in a guided state without hydraulic shock, so the mixing force is almost unchanged since it has intact energy with almost no loss of energy.

In this way, the oxidation gurota of the present invention can be arbitrarily adjusted from the maximum to the minimum amount separately by the lifting and lowering of the scattering flow control plate 16 with little change in the mixing force.

In this paper, the oxidizing sphere rotor can only freely adjust the oxygen transfer amount to the oxidizing sphere by adjusting only the height of the scattering flow control plate 16, and the mixing force of the oxidizing sphere hardly changes even if the oxygen transfer amount is changed, so the BOD load of the influent sewage or wastewater Even if it is low, it is possible to maintain low dissolved oxygen concentration while maintaining the necessary mixing power, and to increase the denitrification effect by facilitating formation of anaerobic sections by maintaining proper dissolved oxygen concentration even when using biological denitrification process such as nitrogen removal.

Claims (1)

An intermediate passage (e) shall be installed at the intermediate position in the longitudinal direction of the oxidizing sphere in the oxidizing port consisting of the external structural wall (a), the intermediate bulkhead (b), and the inlet (c) and the outlet (d). Rota shafts are installed horizontally to be parallel to the surface of the oxidant sphere rotabody 1 so as to be perpendicular to the longitudinal direction in each oxidizing channel so as to be symmetrical with respect to each other. (4), the rotatable shaft (4) is supported by the bearing assembly (5), and the other end of the guro-oxidized main body (1) is provided with a rotatable drive shaft (6) integrally formed on the concentric shaft and the drive shaft bearing assembly ( 7) and the end is connected to the gear reducer 8 so that the rotational force of the driving device is transmitted, and the spiral stirring blades 2, which are arranged at equal intervals on the circumference of the oxidizing sphere rotor body 1, are variously Fixed to form integrally with the guro-oxidized main body 1 to become heat In the outer side of the stirring blade (2) at both ends of the guro-oxidized main body (1), a guide ring (3) is installed in a concentric shape in a circular shape, and about 45 horizontally to the outer structure (A) and the middle partition (B) of the oxide ball. Install the guide grooves 17 having the c-shaped guide grooves symmetrically with each other at an angle of ˜60 °, and fix them with a base screw 22. The guide grooves 17 are integral with both sides of the scattering flow control plate 16. Insert the guide pillar (16-1) formed in the form of a lower portion and insert the elevating screw rod (18) into the screw hole of the guide column (16-1) and cover the top cover plate (19) from the top of the elevating screw rod (18) Tighten with cover plate tightening screw (19-1) and the upper end of the elevating screw rod (18) to install the handle 20 to move the scattering flow control plate 16 by the rotation of the handle 20 to move up and down .