DE4211667A1 - Biological processing of household waste in enclosed dumps - using controllable aerobic and anaerobic processes in waste units penetrated by gas and fluid transporting pipe systems - Google Patents

Abstract

Waste, esp. household waste, is handled within a partly or completely enclosed waste unit. Within the unit biological reaction (speeded up) are initiated. The resulting gases are collected in the top region of the unit and piped off, while water seeps through to the bottom region and is led off. The waste unit, which is built on site, comprises flat horizontal (5) and cylindrical vertical regions (10) of porous material, accessible from the outside by means of pipe systems (6,7,9) which transport the biological decomposition products from the unit or deliver any necessary nutrients, air or water to speed up the reaction. The pipe systems (6,7,9) are divided into separate gas and fluid systems and where they occur in the horizontal layer (5) the gas transporting pipes (7) are arrayed below the fluid transporting pipes (6). The vertical (10) and horizontal (5) regions pipe systems are independent. The waste unit has a temporary cover (13). USE/ADVANTAGE - The process is carried out on site and produces composted inert end products. In comparison with the main alternative of incineration there are no dangerous air emissions.

Description

The invention relates to a method for the treatment of Waste, especially household waste, according to the preamble of Claim 1.

The landfill of waste is particularly with municipal Waste remains the most widespread in Central Europe widespread method of waste disposal. Landfills are usually set up and operated so that a Threats to groundwater from contaminants Landfill leachate using a landfill base seal in Connection with retention properties of the substrate on Landfill site and with a surface seal so far avoided as possible and the available landfill volume through the greatest possible compaction of waste in the landfill body be optimally used.

Municipal waste such as B. household waste, consist of a Mixture of organic and inorganic solids that with different moisture contents inhomogeneous in Landfill bodies are distributed. Through chemical-physical and biological processes occur in the landfill body Implementations that help to enrich the leachate with Ingredients and lead to gas production. For the Implementation processes require water that as Heat transport medium and needed for nutrient redistribution becomes.

Depending on the composition, compaction, moisture etc. of the landfilled waste, aerobic and anaerobic processes take place in the landfill body. In the case of smaller, only slightly compacted landfills, the processes are often still aerobic, ie with access to air; When the organic components are aerobically broken down, carbon dioxide (CO ₂ ) is the predominant gaseous end product. In the case of highly compacted landfills, the aerobic process only takes place in the uppermost, not yet compacted and covered position, since the oxygen present in the installation phase is used up very quickly. In addition, the decomposition of the organic waste is largely anaerobic, ie in the absence of air, so that usually a brisk gas production sets in, often intensified by the storage of sewage sludge. The end product is a mixture of predominantly methane (CH ₄ ) and carbon dioxide (CO ₂ ). The negative consequences of gas production can be seen in dangers for people and buildings as well as in damage to vegetation and last but not least in odor emissions.

In such landfills, the biological Implementation processes are not controlled; aerobic, anaerobic processes and leaching of Metal connections run more or less simultaneously, so that the ingredients of the leachate are also very complex and depend on the phase in which the Landfill just located. A surface seal of the Landfill leads to a reduction in leachate, consequently also biological activity. Thereby mineralization and inertization do not occur of waste used to reduce the hazard potential the landfill would be required; as soon as water again Implementation processes take place again.

For inerting compost it has already become known microbially stabilized rotting material of various origins in to store an ecodepot compactly (DE 40 12 670 A1). Here a material is deliberately used to form a landfill used the first aerobic stage of the Go through the conversion process elsewhere has so that it is suitable for the following anaerobic process stage can be stored compactly. This method requires an appropriate room in addition to the landfill room  for composting and for implementation required time.

It continues to detoxify garbage and sewage sludge known to have a landfill body enclosed on all sides leachate from the landfill itself to sprinkle, which are also additives for detoxification and biological activation can be added (DE 38 33 118 A1). These additives can be oriented that the landfill acidified, so that the free Hydrogen ions the heavy metals from their minerals Replace incoming connections, these through the Irrigation washed down and over drainage with the Leachate can be drawn off and excreted. The Landfill body is covered on all sides by a plastic film enclosed. In the upper area of the landfill body below the surface cover is a Piping system with outlet openings; at the lowest point the landfill is an outlet for leachate intended. Gases can pass through gas domes in the area Landfill surface are deducted. Here too is about Sprinkling beyond a control of the in layers of the Landfill body implementation processes neither intends still possible.

Against this background, the object of the invention to create a way to Implementation processes in a waste deposit, in particular a landfill, to be able to influence that in finite Periods of complete mineralization and Inertization of waste with maximum reduction of Waste volume is reached.

According to the invention, this object is achieved by the characterizing part of claim 1 specified  Features solved.

Advantageous further developments result from the Subclaims.

The invention is based on the knowledge that a complete inertization of those stored in a landfill Waste can only be achieved if that for the Mineralization required aerobic and anaerobic Processes in all parts of the landfill in controllable and can be influenced one after the other. this will achieved according to the invention in that the waste body is interspersed with piping systems, by means of which all Areas of the waste body from the outside with liquid and / or gas can be applied, or by removal of liquid and / or gas the flow of the straight there implementation processes taking place can be controlled.

The process according to the invention has the advantage that it is "on site ", i.e. at the site of a landfill can and in a finite manageable period of time Mineralization and inertization of the waste leads; it offers a real alternative to thermal Waste treatment, d. H. Waste incineration, mainly because of the immission risk shifted to the air path is known to be problematic and not accepted in of the population.

According to the invention, the controlled biological conversion of the waste constituents in the first aerobic process stage includes the conversion of the organic solid and liquid waste materials to carbon dioxide, water and biomass, in the second anaerobic process stage the degradation of the biomass formed under aerobic conditions and the further conversion of the waste under Formation of methane (CH ₄ ), hydrogen sulfide (H ₂ S) and biogas and, if necessary, then the leaching of the metals from the waste in the sense of biological mobilization of metal sulfides by biological oxidation under aerobic conditions and their discharge via the leachate detection system.

The prerequisite for the running of these processes is for everyone Process stages an optimal supply of process water in the Landfill. If necessary, the landfill leachate in the Circulated and can also provide nutrients for the Microorganisms are supplied. Because regardless of the Liquid supply also the gas supply, especially the Entry of air or oxygen, must be checked two separate piping systems are required.

If necessary, being an energy supplier can be easily organic degradable industrial waste, such as B. Molasses from the Sugar industry. In a known way Way, the leachate can be applied externally biological, physical or chemical processes, such as e.g. B. reverse osmosis, ion exchangers, stripping colon, be processed.

The method according to the invention can be used both in a landfill usually provided with a base seal, as well as in a waste storage facility that at least at the base with a controllable and Repairable enclosure is equipped as z. B. The subject of EP 0 283 491 B1.

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

Fig. 1 a located a partial cross section through the edge region in the structure and according to the method according to the invention to be operated waste disposal site with a base seal,

Fig. 2 shows a corresponding partial cross section through a landfill with controllable and repairable basic enclosure.

The landfill represented in Fig. 1 in partial cross-section through the edge portion is applied in a trough and has a lower Deponieauflagerschicht 1 formed in a manner known per se landfill base seal 2. A drain layer 3 , in which a leachate collection system 4 is embedded, lies above the base seal 2 . The actual construction of the landfill body according to the invention then begins on this drain layer 3 .

The structure of the landfill body according to the invention initially includes a lowermost permeable layer 5 , which can consist of a uniform material, but in which piping systems 6 and 7 with outlet and inlet openings, which are different and can be acted upon separately, are embedded in planes; this creates two layers 5 a and 5 b. This permeable layer 5 is followed by a layer of waste 8 , followed by a permeable layer 5 with corresponding piping systems 6 and 7 , over which in turn a waste layer 8 is deposited, etc. The topmost waste layer 8 is still under construction in the illustration; if necessary, further layers can follow.

In addition to these horizontal permeable layers 5 with pipe systems 6 and 7 , the landfill body is also penetrated by pipes in the vertical direction. These are in the form of vertical tubes 9 in cylindrical bodies 10 , also made of permeable material and with a more or less circular cross section, which are pulled up with the structure of the landfill body. In the center of this body 10 is a pipe 9 , which, like the pipes of the pipe systems 6 and 7 , preferably made of plastic pipes, for. B. PEHD, optionally with a steel core reinforcement. The pipes 9 running in the cylindrical bodies 10 are connected above the landfill by hose or pipelines 11 , via which the landfill gas generated in particular in the anaerobic phase is drawn off by pumps which are attached to or outside the landfill surface. For good ventilation of the waste, the landfill gas can also be extracted in the aerobic phase, which leads to faster microbial degradation.

The horizontal layers 5 , as well as the vertical cylindrical bodies 10, are made of permeable material in order to prevent the outlet or inlet openings of the piping systems 6 , 7 and 9 from becoming clogged. This permeable material can be an air-permeable drain material known per se, e.g. B. filter gravel or broken material; however, preferably recycling material such. B. slag, broken building rubble, broken concrete sleepers or the like can be used. Against infiltration of very fine particles from the landfill body, the edge surfaces between filter material and waste can be covered by a filter fleece or the like.

The pipeline systems 6 and 7 provided in the horizontal layers 5 are lines 7 for the air supply for the aerobic phase and for the extraction of landfill air to influence the anaerobic phase in the lower layer layer 5 b. The pipe systems 6 located in the upper layer layer 5 a serve in both cases, that is to say both in the aerobic and in the anaerobic phase, for the supply of liquid which, depending on the phase, contains certain nutrients, possibly specially cultivated microorganisms, and possibly also chemicals can be enriched. The preferred liquid is water. A circulation of the landfill leachate is possible, but not primarily provided; It is possible to recirculate microorganisms in the landfill leachate after special treatment.

The arrangement of the piping systems 6 , 7 for the application of gas or liquid such that the irrigation system lies above the ventilation system is important insofar as volatile substances dissolved in the water can be converted from the water to the gas phase in the countercurrent principle. It is therefore an essential feature of the invention to lay the line systems above or below one another in this way.

In the illustrated embodiment, the landfill is still under construction; their final state can be recognized by the later surface seal 12 indicated by dashed lines. In order not to risk uncontrolled entry of rainwater into the body of the landfill under construction, which could interfere with the controllability of the implementation processes that are already taking place during the construction of the landfill in the lower layers, a roof 13 is provided. The temporary canopy 13 can be removed when the final fill level of the landfill is reached; it is then replaced by the surface seal 12 as the actual end cover.

The microbial implementation of the waste has one Volume reduction result, so that with considerable Sacks of the landfill body are to be expected, the Experience has shown that it is not always even over the Base area. As a result, the Surface sealing in the final state, if necessary, renewed or must be repaired to an uncontrolled To prevent the ingress of precipitation and the microbial degradation processes in the landfill through targeted  Liquid and / or air supply through the To be able to control piping systems in a targeted manner.

The method can also be carried out in double-layered landfill systems in which there is an air space between the inner enclosure of the waste and an outer jacket as a control and working space; a partial cross section through such a landfill is shown in FIG. 2.

In this embodiment, the landfill sole initially consists of an outer enclosure 14 made of concrete. On this the unitised because of the possibility of repairs inner vessel 16 is superimposed on the support members 15, about which then takes place as described above, the further landfill construction. There is a walk-in space in the area of the support elements 15 , which can be used for control and repair purposes.

Claims (8)

1. A method for treating waste, in particular domestic waste, in which the waste in an at least partially enclosed waste body, for. B. a landfill, is treated in a way that promotes the biological conversion process, the leachate in the lower part and the gases produced during the biological conversion in the upper part of the waste body being collected and discharged,
characterized,

• - That the waste body is built up in layers, areas ( 5 , 10 ) being provided in the horizontal and / or vertical direction at substantially equal distances from one another, which are provided with piping systems ( 6 , 10 ) which can be acted upon from outside the waste body and which have outlet or inlet openings. 7 , 9 ) for the introduction and / or discharge of liquids and gases are interspersed and
• - That the waste body via these piping systems ( 6 , 7 , 9 ) to promote the biological implementation of the biodegradable or leachable ingredients according to the successive aerobic, anaerobic and optionally leaching process stages liquid and / or gaseous substances are added or removed .

2. The method according to claim 1, characterized in that the areas penetrated by piping systems ( 6 , 7 , 9 ) in the horizontal direction in the form of essentially flat layers ( 5 ) and in the vertical direction in a substantially cylindrical shape ( 10 ) are created . 3. The method according to claim 1 or 2, characterized in that the areas penetrated by the piping systems ( 6 , 7 , 9 ) ( 5 , 10 ) consist of permeable material. 4. The method according to any one of claims 1 to 3, characterized in that separate piping systems ( 6 , 7 , 9 ) for liquids and gases are provided. 5. The method according to claim 4, characterized in that in each horizontal layer ( 5 ) both a pipe system ( 6 ) for liquids, and one ( 7 ) for gases are provided, the one ( 7 ) for gases below that ( 6 ) is arranged for liquids. 6. The method according to any one of claims 1 to 5, characterized in that the piping systems assigned to the individual areas ( 5 , 10 ) are acted upon independently of one another. 7. The method according to any one of claims 1 to 6, characterized characterized in that the waste body during construction is covered against the ingress of precipitation. 8. The method according to claim 7, characterized in that the waste body is provided with a temporary roof ( 13 ).