CS265214B2 - Plastic element for biologic treatment of liquids - Google Patents

Abstract

Plastic insert for biological treatment liquids consist of a group of profiled plates, joined together without glue and fitted with convex and concave ribs, wherein between adjacent profile plates tilted channels with corrugations are formed walls. Profile plates are created of the M profiles whose connecting lines and the center lines are continuous throughout the height of the insert and form an angle with the vertical not more than 30 °. Curled walls are formed ribbed surfaces, molded only on the M-profile arms, with both sides of the connecting lines are planar ribs without ribs. According to a preferred embodiment the plates are connected to each other in opposite directions positions so that the M-profile arms end in contact points. In another embodiment the plates are arranged in the same positions and shifted by 1/2 profile M, so the shoulders profile M on one board lies in the groove at the top of the M profile of the adjacent board.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plastic liner for cartridges of a fluid treatment device, comprising a set of plates provided with concave and convex ribs, wherein undulated sides are formed at an angle between pairs of adjacent plates connected to one another.

As is well known, the quality of water depends on its physical, chemical and biological properties. The protection of water quality and the corresponding efficiency of wastewater treatment have gradually become one of the fundamental problems of environmental protection, especially in recent years.

Various technological processes for the purification of water and waste water by physical, chemical and biological processes are known. In biological processes, so-called drip bodies are used, which are mainly used in the primary phase of a multi-stage wastewater treatment process. These bodies enable the use of active sludge biological technology with higher efficiency.

The inserts and bodies for the dripping device are made of a variety of materials, but in the course of development, only plastic inserts have been developed. The inserts are arranged one above the other and form a tower assembly of individual drip bodies with a water distributor at the top of the tower assembly.

The principle of operation of biological drip bodies is that the waste water flows in an intermittent or continuous stream to the biological film that is formed on the surface of the inserts.

It causes and induces coagulation and absorption of impurities, during which the culture of the micro-organisms forming the biological film dissolves the constituents contained in the water, which are used for energy generation and cell synthesis. The portions of the film that are released when the film layers are excessively formed are collected in the sedimentation portion. By the activity of the separated microorganism enzymes, these portions are broken down into a material that permeates the cell wall and thus participates in metabolic processes.

The oxygen required for biological oxidation is obtained from the air passing through the inserts.

During the run-off of the drip bodies, the BOD value of the wastewater decreases exponentially.

There are some requirements for liners and cartridges that are used for drip bodies: The surface area per unit volume and covered with the biological film should be as large as possible. At the same time, the void volume should be as large as possible in the liners so as to have a sufficiently large free cross section for the flow of wastewater in the form of a continuous film and to ensure a sufficient oxygen supply. In addition, the liners must be resistant to chemical, biological and physical effects and must exhibit sufficient static strength to allow the biological film to support the weight of the water and the multiple liner units arranged one above the other.

Another obvious requirement is the possibility of simple, easy and fast production of inserts as well as the possibility of their quick and simple assembly, operation and maintenance.

Several known solutions have been developed to solve these problems. One of the most well-known versions is described in GB-PS 1 065 612 and 1 080 991. The filling elements are plastic foils or sheets with a straight or curved forming line and with an organically undulating surface. These undulating surfaces are arranged alternating with planar plates or sections thereof such that the elements are arranged opposite each other.

The basic drawback of these designs is that the intention to increase mechanical strength using planar plates, on the other hand, manifested itself in a small specific surface area of 85 m / m, resulting in low efficiency.

It is also known that inserts consist of plates corrugated in strips, the plates additionally being provided with grid reinforcing elements at the top and bottom. This system is not a closed channel system and although the specific surface area of these elements is larger than in the previous solution, the mechanical loading capacity of the inserts is low.

DE-PS 1 299 665 discloses an insert which is similarly composed of organ-shaped plates. The waves of adjacent plates intersect each other and the plates are made of a moisture absorbing material. The specific surface area is relatively small, the mechanical strength is low and the plates are not suitable for filling the biological drip bodies.

Another solution is known from DD-PS 58 104, according to which the filling consists of trapezoidal corrugated plates. Placed between these corrugated plates are planar plates provided with elongated slots as well as corrugated plates. The specific surface area is small, the mechanical strength is low and the range of use of these plates is limited to bringing liquids and gases into contact with each other.

The plastic liner described in HU-PS 172 169 represents some progress compared to previous solutions. This is achieved by providing a plurality of undulating through channels, separated from each other and having a regular hexagonal cross-section in all horizontal planes, interspersed with at least a portion of the inserts. The longitudinal axes of the channels in the vertical plane consist of opposing sections following at least a portion of each other; in particular, two adjacent sides of each channel are provided with undulations extending in a direction perpendicular to the longitudinal axis.

3

This design allows the specific surface to be increased to 135 m / m and gives very good results. However, it has two basic disadvantages: the plates forming the inserts are bonded to one another by adhesive.

This is expensive, requires the provision of filler and other additives, adhesive technology increases the risk of accident because the solvents used are poisonous and pose a risk of explosion and leakage of harmful gases.

A further disadvantage is that the longitudinal axes of the channels form a relatively large angle with the vertical (30 to 50 °). Therefore, due to gravity, water flows down to the lower part of the channels.

This means that, especially in the case of significant surface loads, the surface of the inserts contributes only about 50% of its total surface to intensive cleaning. For this reason, the functional flexibility of the cartridge unit relative to changes in service load is relatively low and small in scope.

Clogging, flooding or other defects in the liner requiring repair or maintenance occur quite often even in the most careful operation of biological drip bodies. Adhesive bonding of the plates is also undesirable in that the individual plates cannot then be removed separately and cleaning and maintenance are difficult.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to overcome these drawbacks and to solve the construction of a heavy duty plastic liner intended especially for drip bodies of biological cleaning devices whose manufacture, assembly and maintenance would be unpretentious, cheap, quick and simple and result in a large specific surface area. the operation of this device with an insert according to the invention is to be more efficient and economical.

This object is achieved by a plastic insert according to the invention, characterized in that its plates are arranged in an M-shaped profile and have regularly repeating convex and concave plate sections connected to one another without the use of glue, with channels arranged at an angle between the plate sections with undulating lateral sides, the connecting lines and the center lines of the M-sections shall be continuous throughout the height of the liner and shall be at an angle of not more than 30 ° to the vertical; the corrugated portions are ribbed surfaces formed only on the outer legs of the M-profile so that the planar strips without ribs are on both sides of the connecting lines of the profiles.

In the insert according to the invention, the individual plates are joined together without the aid of an adhesive. The profiles M may have planar or curved surfaces.

The connecting lines and the middle lines of the M-profiles are inclined at an angle of 5 ° to the vertical in a practical construction design. In particular, the rib surfaces are provided with ribs of the antibody M or alternately of the M and V profiles, wherein the connecting lines and the intermediate lines of the profiles, consisting of planar plate sections, are horizontal.

AND

In this case, these profiles may be rounded at their vertices and joints of adjacent arms. The peaks and arms are inclined to each other at an angle of approximately 90 °.

The length of the upper branch of the M-section forming the plate sections is equal to 1 to 200 mm, in particular 2 mm. The width of the flat planar strips at the edges is similarly equal to 1 to 200 mm, in particular 3 mm. The length of the arm profile is 10 to 200 mm, in particular 25 mm. The height of the M and / or V profiles forming the ribbed surfaces is 2 to 16 mm, in particular 5 mm. In particular, the angle between the legs of the profile is 60 °. The length and width of the plate sections constituting the insert are preferably 500 to 3,000 mm, the size of the plates in a practical construction being 500x1,000 mm.

According to a particular preferred embodiment of the invention, the plates of which the liner consists are connected to each other such that the legs of the M-profile end at the connection point. According to another particular embodiment of the invention, the plates are rotated in the same direction, spaced apart and connected to each other at a distance corresponding to one half of the M-profile so that the arms of the M-profile on one plate extend into a groove at the top of the M-profile.

The plastic sheets of which the liner is formed, as well as the entire load of the cleaning device, can be made of polyethylene, polystyrene, polypropylene, polyvinyl chloride or a hard polyethylene film processed by vacuum forming.

The basic advantage of the plastic liner according to the invention is that the specific surface area is increased up to even 2300 to 500 m / m, which is several times the value achieved in the known solutions. The liner acts as a resilient structure even under high hydraulic or surface loads, so that the device charge may contain a smaller number of liners, reduced by up to 30 to 40 zachování, while maintaining the required capacity of the device.

Two types of inserts can be formed from the same shaped plastic plates, depending on their relative position, one type being formed from the same oriented plates and the other from opposite oriented plates. The joining is carried out by shaped joints so that gluing of the plates is not necessary. The plates can also be easily disassembled and reassembled for cleaning or breakdown inserts, and each plate can be replaced separately with a new plate.

The empty volume of the inserts is large and the angular deviation of the channels with respect to the vertical is small, ensuring an efficient supply of a considerable amount of air.

Due to the special shaping of the top region of the plates, the static strength of the liner is very good and the structure is functional even under considerable mechanical loads.

The plastic sheets of which the insert according to the invention is assembled can be manufactured easily, quickly and in the required size, the production technology being adapted to the existing production technologies.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE PLASTIC INSERT FOR WATER WATER TREATMENT PLANTS, FIG. 1 is a side view of a liner consisting of plastic plates; FIG. 2 is a cross-sectional view of the liner taken along line AA of FIG. Fig. 3 is a cross-sectional view taken along line BB of Fig. 2; Fig. 4 is a cross-sectional view of the ribs in another construction; Fig. 5 is a cross-sectional view of another exemplary rib; 7 is a top view of another alternative embodiment of the insert.

The insert according to the invention constituting the filling of the liquid treatment device consists of profile plates 2 (FIGS. 1 and 2) formed of M 2 profiles which are arranged side by side and connected by their arms 2 along the connecting lines 5. and the center lines 7 at the junction of the upper branches 6 form a vertical angle [alpha], which in this exemplary embodiment is equal to 5 [deg.]. The length of the arms of 2 M 2 ^θ profiles 25 mm, the length of the upper branches 6 is 5 mm. Angle δ between arms 2 3 ^e 90 °.

Shoulders 2 2 M profiles are provided with a ribbed surface 2 · ribbed surface 2 does not take place in the entire length of the profile arm 3, but ^{in the} vicinity of the connecting lines are arranged two planar flat strips 2 without ribs, whose minimum width is 5 mm.

Giant. 3 shows a cross-section of the ribbed surface 8, taken along the plane BB of FIG. 2. The ribbed 8 is formed by alternately arranged and interconnected M-profiles 10 and V-profiles 11, respectively: M-profiles 10 and The V-profiles 11 are rotated opposite each other. The height of the M-profile 10 is 3 mi?. 'hel y between his shoulders is 60 °.

The ribbed surface 8 can of course also be formed in another shape, for example according to FIG. 4, where it consists of profiles V connected to each other and turned to opposite positions. Giant. 5 shows a cross-section of a ribbed surface 2 according to another possible embodiment, wherein the profiles of the individual ribs have a trapezoidal shape. The profile plate 2 can be formed of a synthetic film, for example polyethylene, polystyrene, polypropylene, polyvinyl chloride or hard polyethylene and the like.

The insert according to the invention may be composed of individual profile plates 2 'which may have several basic spatial arrangements.

In the exemplary embodiment of FIG. 6, the profiled plates 2 arranged in the same direction and connected to each other in the half-width points M profiles 2. In this configuration, the angle between the arms 2 is the same as the angle between the upper branches <o, so that the arms 2 ^{do not} bo profile plate 2 extend into the grooves 4 formed between adjacent upper branches 2 of adjacent profile plates 2.

Thus, in the closed cross-section insert, channels 12 of square or, in this exemplary embodiment, of trapezoidal cross-section are formed, whereby only the groove area formed by the upper branches of the profiles M2 is missing in the full square or trapezoidal cross-section.

The surface area of the closed cross-sectional liner shown in FIG. 6 per unit volume 23 is considerably large and can reach up to 500 m / m.

In the alternative embodiment shown in Fig. 7, the insert according to the invention also has a large specific area, although its value is slightly lower than in the example of Fig. 6. The profile plates 2 are in this case always mounted in opposite positions and are mutually connected so that the arms of the M-profiles end at the points of interconnection in horizontal planes.

In this example, since the connecting lines 2 ^{and the} center lines 7 on the profile plates 2 are always in opposite positions to each other, no closed cross-section occurs in this example.

The measuring surface of the insert made up of the profile plates 2 according to the examples of FIGS. 6 and 7 is several times larger than in the prior art solutions and the relatively small angle between the profiles and channels with the vertical provides both high stability and optimum operating conditions. The polluted water is intensively cleaned on both sides of the profile plates 2 under variable or pulsed surface loads, which is made possible by the structure being able to react flexibly to changes in surface load.

The speed of water flowing down the profile plates ³ and 2 controlled finned surfaces 2 · The ribbed surfaces 8 facilitate attachment of biofilm and increases surface area.

The liner according to the invention thus increases the efficiency of the biological drip bodies, with the amount of filling being reduced by 30 to 40% and the manufacturing and operating costs reduced by 40 to 50%.

Although only one of the possible alternatives is described in the exemplary embodiment, it is clear that several other versions and alternatives can be made based on the same principles. In particular, the sizes and shapes of the M and V profiles may be varied. The undulating surfaces may be formed differently than in the embodiments shown in the drawings, the peaks in the region of the joints of the profiles or within the profiles may be rounded. However, all these changes do not change the essence of the invention, in particular the stability of the system of individual profile plates joined and disassembled without the use of glue, while also maintaining the advantage of low acquisition and operating costs and increased functional efficiency.

Claims (12)

Plastic insert for biological treatment of liquids, consisting of profile plates provided with concave and convex ribs, wherein oblique channels with wavy side walls are formed between adjacent profile plates, inclined with respect to the vertical axis, characterized in that the profile plates are formed of M-shaped profiles (2), where the connecting lines (5) and center lines (7) of the individual profiles (2> are integral over the entire height of the insert and form a vertical angle α equal to 3 ° to 30 ° where the corrugated side walls are formed ribs (8) formed on the legs (3) of the profiles (2), wherein smooth planar strips (9) are formed on both sides of the connecting lines (5). Plastic insert according to claim 1, characterized in that the profile plates (1) are connected to each other. Plastic insert according to claim 1, 2, characterized in that the M-shaped profiles (2) are formed by flat surfaces. Plastic insert according to claim 1, 2, characterized in that the M-shaped profiles (2) are formed at least in part by curved surfaces. Plastic insert according to one of Claims 1 to 4, characterized in that the connecting lines (5) and the center lines (7) of the M-shaped profiles (2) form an angle rov 5 ° with the vertical. Plastic insert according to Claims 1 to 5, characterized in that the ribs (8) are formed by flat plates whose connecting and center lines are horizontal. Plastic insert according to claim 6, characterized in that the ribs (8) are formed by M-shaped profiles (10) or V-shaped profiles (11). 8. Plastic insert according to claim 1, characterized in that:. the M-shaped profiles (2), the M-shaped profiles (10) and the V-shaped profiles (11) are rounded at the points of the legs and joints of the arms. Plastic insert according to Claims 1 to 8, characterized in that the legs (3) of the M-shaped profiles (2) form an angle β of 15 ° to 178 ° together. Plastic insert according to claim 7, characterized in that the legs of the M-shaped profile (10) forming the ribs (8) form an angle Y of 15 ° to 178 °. Plastic insert according to one of Claims 1 to 11, characterized in that the profile plates (1) are turned in the same direction, connected to each other and spaced apart by one half of the M-shaped profile (2) and the arms (3) of the M-shaped profile (2). One profile plate (1) lies in a groove (4) formed in the upper part of the M-shaped profile (2) of the adjacent profile plate (1). Plastic insert according to one of Claims 1 to 11, characterized in that the profile plates (1) are placed in mutually opposite positions and the arms (3) of the M-shaped profiles (2) terminate in a horizontal section at the point of connection thereof.