DE3420091C2 - - Google Patents

Description

The invention relates to a plant for wastewater treatment by microorganisms, their containers with pipe systems for the supply of waste water and the discharge of the Microorganisms treated water is equipped and at least one device arranged in its interior for contains the adsorption of microorganisms by Scaffolding with elastic stretched on this, the volume of the Device is formed evenly filling cords, and a device for the regeneration of this device and a facility for the formation of a wastewater stream and the Direction of this flow in the device for adsorption of microorganisms.

Such a system is known from GB-PS 21 06 493. At this well-known system are on the strings of each other spaced sponges arranged. Here, however, only the biological film on the surface of the sponges immediate Contact with the wastewater to be treated. The entry of Dirt in the sponge is difficult and the one located there Microorganisms make only a small contribution to Cleaning process. Furthermore, a polyurethane sponge only a lifespan of 1.5 to 2 years, so that at the latest then the system is shut down and the sponges are replaced have to.

The object of the invention is to provide a system for Waste water treatment according to the preamble of patent claim 1 to improve in that the adsorption area of Microorganisms are essential with less material is enlarged and has a longer lifespan.  

This task is characterized by the characteristics of the Claim 1 solved.

Advantageous embodiments of the invention are the subject of Subclaims 2 and 3.  

The design of the device for the Adsorption of microorganisms ensures a temporal unchangeable large adsorption area, increases the Regeneration ability of the adsorbent and reduced the hydraulic resistance of the adsorbent for the flow of the water to be treated. The above Advantages are achieved in that the adsorbent is designed in the form of flexible cords under even Filling with orderly attached, individual Fiber sections. It is well known that glass fibers with a diameter of up to 50 µm an increased adsorption capacity for microorganisms. Therefore generated an orderly position of individual glass fibers in the room the device has a larger total area of the adsorbent. An equal surface charge on the fibers and fixing one of the ends of the fiber sections in one prevent certain point in the space of the device a clumping of the fibers and a change over time the adsorption area.

The flexibility and elasticity of the on the Scaffolded cords of the adsorbent simplifies and facilitates its regeneration because the Pulsation of a rinse water stream vibrating the cords causes and the tearing of the biomass from the Surface of the adsorbent facilitated. The presence elastic and flexible cords and individual fibers  in the entire space of the device for adsorption of microorganisms calms the turbulent Pulsation of the water flow to be treated, a Laminarization of the current and consequently a reduction the hydraulic resistance of the adsorbent for the flow of water to be treated and energy consumption the plant. The rational use of the surface each fiber for the adsorption of microorganisms and the low volume of the fibers reduce the Material costs of the system. Due to the large total surface of the Adsorbent and its high adsorbability there is a large amount of sessile microorganisms in the plant a high performance the system compared to known systems of the same type. The increase in the permeability of the system allows a reduction in their size compared to known ones Investments.

It is most advantageous if the cords on the Scaffolding are attached so that the distance between the geometric axes of the cords 0.8 to 5 times the length the glass fiber sections is. Such an execution of the Scaffolding and filling its volume with cords allows maximum use of the surface of the Glass fibers because the fibers do not overlap each other and so free access of the microorganisms to the adsorbent  is created, which in turn the performance of Plant increased. An arrangement of the cords at a distance less than 0.8 times the length of the glass fiber sections no significant increase in the area of the adsorbent, while arranging the cords at a distance of over 5 times the length of the glass fiber sections in the framework a room with a low content of microorganisms creates.  

Because the device installed in the container for absorbing microorganisms is rotatable about its horizontal axis of symmetry and off concentric frameworks with a spiral shape each frame is wrapped with cords, can  the advantages known systems with submerged biofilters in relation on the economy of the saturation process of the Water with oxygen and the spatial distribution of the microorganisms adhering to the adsorbent and these benefits with better exploitation the ability of the microorganisms to flocculate unsolved admixtures and with better developed surface of the adsorbent connected be, which in turn increases the performance of the plant ensures the need for additional establishment Wastewater treatment plants eliminated and consequently the operation of biological wastewater treatment plants simplifies and relieves what is special is important in rural areas.  

When enlarging the dimensions of a plant for the clarification of small amounts of waste water by microorganisms contains every device for adsorbing Microorganisms concentric frameworks that are combined into blocks, their number, shape and location form a shape of the device creates that comes close to that of a rotating body, where the central block is fixed on a hollow shaft and the remaining blocks on the outer surface of the central blocks are arranged.

Block construction of the device for adsorption of microorganisms allows an increase in Degree of prefabrication and mechanization and automation the manufacturing process of the device. Furthermore is the assembly and disassembly of individual blocks of the Device for adsorbing microorganisms less labor-intensive as the assembly and disassembly of a Device with the same dimensions, not in block construction  is executed. That's why it's big Dimensions of the device for adsorbing microorganisms advantageous to block the device assemble assembled scaffolding.

If devices for the adsorption of microorganisms come to use, which put together into blocks Scaffolding included are inside each block Perforated pipes for feeding along the axis of symmetry of air into the device for adsorbing attached by microorganisms.

The presence of perforated tubes for feeding prevented from air into the adsorbent the formation of anaerobic zones inside the device and ensures high oxidation rates of the Impurities.

The invention will now be described with reference to the drawing explained. It shows

Figure 1 shows the overall view of a plant for the clarification of small amounts of waste water by microorganisms in a perspective view.

Fig. 2 shows a section along the line II-II in Fig. 1;

Fig. 3 is a section along the line III-III in Fig. 1;

. Figure 4 shows the overall view of a device 1 for adsorbing microorganisms in Figure in a perspective view.

Figure 5 is a general view of an apparatus for adsorbing microorganisms having assembled into blocks scaffolds in a perspective view.

Fig. 6 is a general view of a flexible two elements and Glasfaswerabschnitten composite cord;

Fig. 7 is a section along the line VII-VII in Fig. 6.

In Fig. 1, a plant for the purification of small amounts of waste water by microorganisms is shown, which contains a frame 61 with water-impermeable lateral boundary walls 62 , to which a plurality of containers 63 are attached, the cylindrical bottoms 64 and conical collecting trays 65 with openings 66 for draining the Mud and gate valve 67 ( Fig. 3) have. The structural design of the container is shown in FIGS. 2 and 3. The system is equipped with a line system 68 for the supply of the waste water and a line system 69 for the discharge of the waste water treated by microorganisms. Each container 63 of the system has its own device 70 ( FIG. 4) for the adsorption of microorganisms, which consists of concentric, cylindrical frameworks 71 with flexible cords 16 , which consist of at least two flexible elements 17 ( FIGS. 6 and 7) and in substantially perpendicular to these elements 17 and between fiberglass sections 18 located between them, which are attached to the elements 17 so that a connection of the type of a round brush is formed, which is shown in Fig. 6. The frames are at a distance of 0.8 to 5 times the length of the glass fiber sections 18 . The cords 16 are wound spirally on the longitudinal connections 72 of the stands 71 delimited by wheels 74 at the end so that the turn of the spiral is 0.8 to 5 times the length of the glass fiber sections 18 . The longitudinal connections 72 of all cylindrical frames 71 are attached with their ends to spokes 73 of the wheels 74 of the device 70 for the adsorption of microorganisms. The centers of the wheels 74 of the device 70 are fixed on a horizontal shaft 75 , which at the same time represents the axis of symmetry of the device 70 for the adsorption of microorganisms. The shaft 75 is connected to an electric motor 77 by a drive 76 . Scraper 78 are attached to the outer cylindrical frame 71 at an angle to the axis of symmetry of the device 70 for adsorbing microorganisms in the direction of rotation of the shaft 75 such that the end of a scraper 78 is in a plane perpendicular to the shaft 75 with the beginning of the next scraper 78 is located.

The device for the regeneration of the device 70 for the adsorption of microorganisms contains perforated tubes 79 which are connected via valves 80 to a line system 81 for the supply of air into the containers 63 .

The system contains a device for the formation of a wastewater flow and its guidance into the device 70 for the adsorption of microorganisms, the function of which is controlled by a water overflow 82 which is connected to the power system 68 for the supply of the wastewater, a water overflow 83 which is connected to the Pipe system 69 for the discharge of the water treated by microorganisms is connected, and water overflows 84 , which are created by assembling the cylindrical bottoms 84 of the containers 63 at the surface line of the cylinders, are exerted.

The plant for the treatment of small amounts of waste water through microorganisms works as follows.

In the form of a frame 61 with a water-impermeable lateral boundary wall 62 , the sewage flows from the line system 68 for the supply of the sewage via the water overflow 82 into the first tank 63 provided in the sewage treatment process. The device 70 for adsorbing microorganisms rotating on the shaft 75 by the electric motor 77 and the drive 76 , consisting of the frameworks 71 , which are designed in the form of concentric cylinders, the longitudinal connections 72 of which have their ends at the spokes 73 of the wheels 74 are half-lowered into the water to be treated. The cords 16 wound spirally on the longitudinal connections 72 of all cylindrical frames 71 are in alternating contact with the water to be treated and with the air. The microorganisms adsorbed on the surface of the glass fiber sections 18 extract organic compounds from the wastewater and convert them partly using the atmospheric oxygen into cell mass of the multiplying microorganisms and partly by oxidation into simple inorganic compounds. In addition, the cells of the microorganisms flocculate undissolved admixtures of the wastewater and reduce the resistance of the koilloid system to the wastewater contaminants, which in turn leads to the precipitation of some of the substances suspended in the water as sludge onto the cylindrical bottom 64 . The scrapers 78 push the sludge into the conical collecting pan 65 and further over the gate valve 67 into the openings 66 for dewatering and recycling. When overflowing over the water overflows 84 from one container 63 into the other, the wastewater loses organic substances and undissolved admixtures, is clarified and passes through the water overflow 83 into the line system 69 for the discharge of the treated water. When coagulates consisting of microorganisms and undissolved admixtures accumulate on the surface of the glass fiber sections 18 , the adsorbent of the device 70 is regenerated periodically. For this purpose, the valve 80 is opened, and when air is let through the perforated pipes 79 connected to the line system 81 for supplying air to the containers 63 , the coagulates are detached from the adsorbent in strips so as not to affect the quality of the cleaned Water deteriorate.

The number of perforated tubes 79 and valves 80 in each container 63 corresponds to the number of strips over the entire length of the device 70 for adsorbing microorganisms which can be regenerated when the valve 80 is open.

A variant according to FIG. 5 is provided to increase the performance of the plant for the treatment of small amounts of waste water by microorganisms.

The device 85 for the adsorption of microorganisms ( FIG. 5) in the above-mentioned system contains scaffolds 86 , which are combined into blocks 87, 88 , the number, shape and location of which creates a shape of the device 85 for the adsorption of microorganisms, which the of a rotating body comes close. The central block 87 is fixed in place on a hollow shaft 89 , and the remaining blocks 88 are arranged on the outer surface of the central block 87 . Inside each block 87, 88 there are perforated tubes 90 along the axis of symmetry for the supply of air into the device 85 for the adsorption of microorganisms.

One end of the hollow shaft 89 is welded closed, while the other end is connected to a line system 91 for the air supply. The perforated tubes 90 are connected to the hollow shaft 89 via connecting lines 92 . Scraper 93 are attached to the outer surface of blocks 88 .

The plant for the clarification of small amounts of waste water by microorganisms in the variant described above functions similarly to the plant shown in FIGS. 1, 2, 3 and 4, with the difference that in the device 85 for the adsorption of microorganisms through the performed pipes 90 air is fed. The air passes from the line system 91 for the supply of air through the hollow shaft 89 and the connecting line 92 into the perforated pipes 90 . The introduction of air into the device 85 for the adsorption of microorganisms prevents the formation of anaerobic zones in the interior of the device 85 and ensures high rates of oxidation of impurities with small dimensions of the device 85 for the adsorption of microorganisms.

The plant for wastewater treatment by microorganisms has the following advantages compared to known plants in which devices for the adsorption of microorganisms are used:
- 40 to 100 times larger adsorption area;
- 5 to 40 times less material;
- 2 to 3 times smaller dimensions of the system;
- energy consumption reduced by 2 times;
- easier to build and use.

It is also used as an adsorbent Material durable, not scarce and also not difficult to get.

Claims (3)

1. Plant for the treatment of wastewater by microorganisms, the container ( 63 ) of which is equipped with line systems ( 68, 69 ) for the supply of wastewater and the discharge of the water treated by microorganisms, and at least one device ( 70, 85 ) arranged in its interior contains the adsorption of microorganisms, which is formed by scaffolds ( 71, 86 ) with elastically stretched cords ( 16 ) which evenly fill the volume of the device, and a device ( 79 ) for regenerating this device and a device for forming a Contains wastewater flow and the control of this flow in the device ( 70, 85 ) for the adsorption of microorganisms, characterized in that the device ( 70, 85 ) for the adsorption of microorganisms is rotatable about its horizontal axis of symmetry and has at least one space grating that made of concentric scaffolds ( 71, 86 ) with spiral au f elastic cords ( 16 ) stretched over each scaffold, the cords being composed of at least two flexible elements ( 17 ) and essentially perpendicular to these elements ( 17 ) and glass fiber sections ( 18 ) located between them, which are thus attached to the flexible elements ( 17 ) are attached so that a connection of the type of a round brush is created. 2. Plant according to claim 1, characterized in that the concentric frameworks ( 86 ) are combined in blocks ( 87, 88 ), the number, shape and location of which ensures a structure of the device ( 85 ) for the adsorption of microorganisms, which is a body of revolution comes close, wherein a central block ( 87 ) is fixedly mounted on a hollow shaft ( 89 ) and the remaining blocks ( 88 ) are arranged on the outer surface of the central block ( 87 ). 3. Installation according to claim 1 or 2, characterized in that the cords ( 16 ) are attached to the concentric frames ( 71, 86 ) such that the distance between the geometric axes of the cords ( 16 ) is 0.8 to 5 times the length of the glass fiber sections ( 18 ).