KR900002338B1 - Rotaing contracting - Google Patents

Abstract

A sewage treatment apparatus comprises a container for holding sewage, a rotary biological film propagation bed including a rotary shaft (1), and discs attached to the shaft on which the biological film is formed. The disc consists of two semicircular plate inclined in a direction opposite to that of the other. The apparatus forms more thick biological film on the cylindrical rotary bed and treats sewage with higher efficiency.

Description

Rotary Sewage Treatment System

1 and 2 are side views of the present invention. FIG. 1 is a 180 ° right angle.

2 is a view illustrating angles when a linear plate of 90 ° is used.

3 is a perspective view of FIG.

4 and 5 are plan views for explaining the operation of the present invention.

* Explanation of symbols for main parts of the drawings

1: rotation side 2: linear plate

3, 3 'and 4, 4': Yanbian 6: Sewage surface

The present invention relates to a rotary sewage treatment apparatus.

Rotating the rotating plate while immersing about half of the rotating plate in sewage, repeating dipping and aeration into the sewage flow, oxygen in the air is absorbed, aerobic microorganisms adhere to the surface of the rotating plate to produce a biofilm, and the activity of this aerobic microorganism The rotary plate method is known in which organic matters in sewage are biologically oxygenated to purify sewage.

In the biofilm generated on the surface of the rotating plate in the rotating plate method, a peeling force due to the flow of sewage is applied when immersed or floated with the rotation of the rotating plate. If too small, the biofilm becomes excessively thick and oxygen in the air cannot be sufficiently absorbed to become anaerobic, and in any case, the ability of oxidative degradation is significantly reduced.

Since the magnitude of the peel force is determined by the rotational speed of the rotating plate, in order to keep the biofilm at the desired thickness, the rotational speed must be maintained in a range in which the desired peel force is applied.

However, even if the rotational speed of the rotating plate is the same, it is natural that the linear speed of rotation is changed near the center of the periphery of the rotating plate. Therefore, the larger the diameter of the rotating plate becomes, the larger the difference becomes. It is extremely difficult, and in the vicinity of the central part, the biofilm is excessively thick, so that the gaps between the respective rotating plates may be blocked or become anaerobic, which may significantly reduce the decomposition rate of organic matter.

In the rotary sewage treatment apparatus, each of the rotating plates is generally mounted perpendicular to the rotating side, so that even if the rotating plate rotates, only the same trajectory is slowly followed, but the sewage and air in the space near the center of the rotating plate are Hardly stirred. For this reason, the vicinity of the center of each space interposed between the respective rotating plates is not mixed with each other, and this overlaps with the underspeed of the linear velocity to further blockage near the central portion, thereby substantially reducing the effective area of the rotating plate to allow the sewage treatment apparatus. It was a great cause of lowering the load.

In order to eliminate the above-mentioned defects, the present invention uses a linear plate having required angles as a rotating plate, and mixes sewage and space in each space interposed between each rotating plate to prevent excessive film thickness and lack of oxygen. It is.

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

1 and 3 are views for explaining an embodiment of the present invention, and show the case where the linear plates 2, 2 'having a right angle of approximately 180 ° are provided on the rotation side 1.

In the drawing, four linear plates (2, ..., 2 ', ...) are provided, but in the actual apparatus, these two sets of linear plates are each arranged in parallel through a narrow gap.

These two linear plates (2 ..., 2 '...) have edges (3 ..., 3' ..., 4 ..., 4 ') at right angles, respectively, as shown in Figs. It is a linear arrangement arranged in one plane, and the edges (3 ...) of the other jaw are bent and opposed to the edges (3 '...) of the other jaw in opposite directions. However, the cross-sections of the edges (3…, 3 '…) and the edges (4…, 4'…) of the linear plates face each other with steps, and since the different trajectories are slowly rotated, the sewage and air are double edges ( 3,3 ') and through the gap between the edges (4,4') are mixed with each other.

Therefore, the greater the number of edges facing each other, the better the mixing of sewage and air. FIG. 2 is an embodiment in which four sets of linear plates (2 ..., 2 '..., 2 ..., 2' ...) are formed by dividing the rotation circumference into quarters and having an approximately 90 ° angle. In this case, the mixing of the sewage 6 and the air is carried out through the gap formed by the edges (3 ..., 3 '..., 4 ..., 4' ...), and the number of the gaps is twice as large as the right angle is 180 °. It is therefore obvious that the mixing of sewage and air is as good as that.

Thus, according to the present invention, it is possible to mix sewage and air in each space interposed between each rotating plate near the rotation side, which was not possible in the related art, and to improve the mixing of sewage and air by increasing the number of gaps between opposite edges. Can be.

4 and 5 are diagrams for explaining the combination of sewage and air in the case where the linear plates are arranged in this way.

Air (9…) interposed between one linear flat plate (2…) is in the vicinity of air (10…) and edge (3, 3 ') interposed between the other linear plates (2'…). Communicating. Therefore, when the linear plates 2, 2 'are rotated, the sewage and the air in the space 9 interposed between one linear plate (e.g., symbol 2) are the edge 3' of the other linear plate 2 '. Collide with and move into two spaces 10 as indicated by arrows 7. However, since the edges 3, 3 'of the linear plate 2' are bent, only a portion corresponding to the bending along the rotation of the linear plate 2 is extruded while its position is forcibly divided into two minutes. Is moved to the space 10.

Further, when the edges 4... 4,... And bending of the linear plates forming the space 9 are bent in the same direction as the edges of the linear plates 3... 3,... 3…, 3 ′…) are moved in the reverse direction by a substantial amount extruded forcibly and return to their original position. This movement is carried out continuously while the rotation is performed, whereby mixing of sewage and air is done sufficiently. Although FIG. 4 and FIG. 5 show only the movement of waste water and air, respectively for convenience, the movement of FIG. 4 and the movement of FIG. 5 are performed simultaneously. Since such mixing and stirring is performed in all parts of all edges, it is clear that the mixing ratio of sewage and air is dramatically improved compared with the conventional one.

As described above, according to the present invention, mixing and mixing of sewage and air are performed through the leading edges of the respective linear plates, so that there is no fear that the thickness of the biofilm will be excessive or anaerobic even near the rotation side. For this reason, the allowable load amount is much larger and extremely advantageous than the conventional rotary sewage treatment apparatus.

Claims (2)

In the rotary sewage treatment apparatus for purifying the sewage by rotating the rotating plate while immersing a portion of the plurality of rotating plate mounted on the rotating side in the sewage, the rotating plate is formed of a linear plate with the required right angle, These linear plates are divided into circumferences on the rotational side, and are composed of a plurality of sets arranged in a line along the sidelines on the rotational side, and the linear plates of these respective groups are the edges of the linear plates opposite to the corresponding other groups. Rotary sewage treatment apparatus, characterized in that the configuration is bent in opposite directions. 2. The rotary sewage treatment apparatus according to claim 1, wherein the linear plates are arranged by changing the phases of the linear plates of the other pair corresponding to each other and their attachment positions.

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