NL1010703C2 - Treatment of biological waste or contaminated soil - Google Patents

Abstract

Process for treatment of biological waste or contaminated soil comprises forming a first layer of the waste or soil on a surface, growing rhizomatous plants on the first layer, harvesting the plants, depositing a second layer of the waste or soil on the previous layer and treating it in the same manner, optionally repeating this process one or more times, and disposing of the residual material. The depth of the second layer must be such that the plants' rhizomes can grow through it.

Description

Method for processing biological waste as well as for cleaning contaminated soil

The invention relates to a method for processing biological waste, in particular of contaminated compost, of biological waste material generated in the food industry, of sewage sludge and the like, and for cleaning in particular with heavy metals or soil contaminated in other ways, whereby a first layer of the biological waste is first resp. apply the contaminated soil to a surface, let plants grow on this layer, harvest the plants, then apply a second layer of the biological waste resp. apply the contaminated soil to the previous layer and treat it in the same manner, whereby the method is optionally repeated once or several times and finally the residual residue of the biological waste resp. save the ground.

The invention also includes the cleaning of soil contaminated with chemical substances such as calcium, nitrates and other salts as a result of the over-fertilization of agricultural soils with manure, farmyard manure or fertilizer. The term "organic waste" used in this application also includes sludge from washing sugar beets, waste from coffee roasters, breweries, fruit must plants, wine presses, fruit juice producers, the food canning industry, etc.

25 In the context of the reduction of waste generated, particularly in private households, the waste is pre-sorted by the consumer and disposed of separately. In addition to the separate processing of waste paper, glass and plastics, waste containers for compostable materials, e.g. spoiled and unused food for other reasons. The contents of these containers are transported to composting plants, where they are composted in known manner and finally applied on agricultural land. The compost obtained serves to improve the soil and as a nutrient for the cultivated plants.

However, it is only possible to apply the compost on agricultural land without problems if the starting material is not contaminated with foreign substances. Unfortunately, such contaminants are present in the organic material from private households and sent to the composting plants. Pieces of glass can thus be placed therein. plastic and metal parts, toxic substances, exhausted batteries, manure, weed seeds, etc. are found. These components not only lead to a bad odor of the compost that has arisen, but also complicate or even prevent its processing.

After the application of the compost produced from biological household waste to agricultural land, a waiting period of about 1 to 2 years must be observed for legal reasons, before such compost is again applied to the same surface. With the currently increasing amount of such compost, ever greater transport distances to suitable agricultural land are the result. In addition to the correspondingly increasing costs, the increasing driving capacities of the trucks are also a disadvantage for environmental reasons. Finally, the demand for suitable agricultural land increases the costs of applying the compost.

After the new biological waste and compost law planned by the German Federal Government, a sharpening of these problems can be expected, because in future there will only be a maximum of 20 to 20 tons of biological waste, depending on the maximum content of heavy metals and requirements with in relation to epidemic and phyto-hygiene, can be applied to one hectare of agricultural land within three years. In addition, studies on harmful substances are prescribed every quarter. Lighting is only available for unmixed biological waste such as bark 25 and green waste.

The problem of the invention therefore lies in the development of a particularly economical method for processing biological waste and for cleaning, in particular, soil contaminated with heavy metals, and eliminating the above-mentioned drawbacks. The concepts of "biological waste" and "contaminated soil" were explained in more detail in the beginning by means of examples.

The problem is solved in the method for processing biological waste and for cleaning contaminated soil by using rhizome-forming plants and by measuring the thickness of the second layer so that the rhizomes of the plants can grow through this second layer .

! According to the invention, a biological separation of the contaminated compost as well as the other biological waste and the contaminated soil into biomass and residues is carried out. The plants convert the organic part of the biological waste resp. the soil into biomass, which is subsequently harvested and can be used as animal feed or in some other manner, which is further explained below. The impurities remain, which are removed in a conventional manner, e.g. can be processed by dumping or incineration. The great advantage of the method according to the invention lies in the considerable volume reduction of the as such worthless biological waste and the contaminated soil. Tests have shown that a reduction of 80 to 90¾ can be achieved.

The advantage of the planting also lies in the reinforcement of the layer of biological waste resp. the base coat, so that no washing out during rain, erosion or weathering takes place. Finally, the aesthetic impression of such an open-air surface 15 is improved. The planting also has the advantage that the method according to the invention does not require buildings for its implementation, but can be carried out in the open air. At most it could be necessary to apply the layers of biological waste resp. seal the primer layers down, e.g. with a plastic foil.

The advantage of the layer-wise method according to the invention lies in the low need for surfaces. On one and the same surface a multiplicity of biological waste resp. soil, which is applied to agricultural land in the usual manner mentioned at the beginning.

25 Rhizome means the rhizome of plants. The working layer by layer can be repeated almost arbitrarily often. Here it is only once. in the beginning, which is necessary to place the plants on the biological waste resp. to plant the contaminated soil resp. to sow. When the plants have formed sufficient root material in this first layer, which can grow through the second layer to be applied, and the aerial parts of the plants have been harvested, the second layer can be applied. The rhizomes of the plants then grow through this second layer and absorb the organic portion of the second layer as they grow. When sowing resp. planting in the winter, after a first planting time of about 8 months, a harvesting step can take place approximately every 3 to 4 months. Therefore, about 3 to 4 new layers can be applied annually.

For later harvesting of the aboveground plant parts and for 1010703 4 the re-application of biological waste resp. of contaminated soil, it is advantageous if the first application of the! biological waste resp. the contaminated soil creates and leaves traces of the usual width for tractors.

5 The choice of the plants used is determined, among other things, by the type of contamination. It is thus preferable to use plants which selectively absorb the impurities, in particular heavy metals, to a lesser extent than the other substances in the soil when nutrients are absorbed. In particular, it is proposed to use buckwheat, shepherd's purse powder, herring puree and / or polygonum as plants for cleaning heavy metal-contaminated soil. In this way, the undesired impurities accumulate in the remaining part of the biological waste which has not been absorbed by the plant, respectively. the contaminated soil. The plant, on the other hand, contains only a small amount of impurities and can easily be used as animal feed or in other ways, e.g. by recomposing to prepare manure or by pelletization, as further explained below.

Annuals are particularly suitable for use in the method according to the invention. Preferably, these plants should be fast growing and produce large foliage masses.

Particularly preferred plants which can be used in the method according to the invention are polygonum, reed, iris, sunflower, bamboo, pampas grass and / or C4 plants.

The said plants are distinguished by a particularly large nutrient absorption, so that the organic part of the biological waste resp. the contaminated soil has been consumed in a relatively short time.

As C4 plants, a series of plant species is indicated which excel due to a high photosynthesis rate. This is based on an effective consumption of carbon dioxide, even with a low CO2 supply. The first detectable reaction product is a C4 body (oxaloacetate, malate, aspartate), in contrast to the C3 body 3-phosphoglyceic acid in the C3 plants. The morphology of the C4 plants differs from that of the C3 plants such that the assimilating cells in the C4 plants are arranged coronately around leaf vein bundles, while in the C3 plants they are usually layered.

It is further proposed that the thickness of the layers is 0.3 to 1 m 101 0703 5. At this layer thickness, the rhizomes of the plants used are readily able to penetrate the newly applied layer, so that no replanting or sowing is necessary. A layer thickness greater than 1 m leads to an undesirably too strong heating, which impedes the growth of the plants.

A further economic improvement of the method in the case of the processing of biological waste is achieved if sand and / or a sand-like material, in particular finely ground construction waste, is added to the biological waste and the layers are at least 1 m thick.

The sand-like material mixed in prevents excessive heating of the applied layer of biological waste, so that layers with a thickness of more than 1 m are also possible.

Preferably, 5 to 10 superimposed layers are applied successively, and only then is the remaining contaminated residue of the biological waste resp. the contaminated soil is processed. If one starts from a layer thickness of 1 m, then at the end of the total process, a layer with a thickness of only about 1 m, which is mineralized or resp. Is sanded and which can be processed in a known manner after the rhizomes present therein, which can be reused as planting material, have been removed.

In addition, in order to avoid a possible odor burden by the applied layers of biological waste, it is proposed that a layer of earth, in particular mother soil, is applied to each layer of the biological waste. For this, a thickness of 5 to 10 cm is sufficient.

It is furthermore advantageous if one processes the remaining remainder of the biological waste resp. the contaminated soil has removed the root material contained therein, in particular by sieving, and, in particular as new planting material or by composting, is reused.

The green waste that is generated during the harvesting of the plants can be reused in various ways. It can be used immediately and without pre-treatment as animal feed and as a mulch. After briquetting, this can be burned in private households or in power stations for heat generation. After composting, high-quality flower soil is obtained.

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In a particularly advantageous possibility, it is contemplated that the green waste obtained after harvesting the plants is ground or chopped. optionally dries, particularly to a residual moisture content of 8 to 10 wt.% or less, and as a litter for livestock and / or pets, e.g. horses, chickens, cats, used. Drying can be carried out with hot air and, for energy saving, the waste heat from a composting device can preferably be used. Furthermore, the ground green waste for binding moisture can also be added to the sewage sludge generated in purification plants before it is applied on agricultural land or subjected to the method according to the invention for processing biological waste.

In a further, particularly advantageous embodiment of the invention, a very high-quality product is obtained from the virtually worthless starting material. To this end, it is envisaged that the green waste obtained after harvesting the plants and / or green waste obtained from other sources is ground or chopped, dried, in particular to a residual moisture content of 8 to 10% by weight or less, and pressed into pellets, which in particular have dimensions of a length of about 1 20 cm and a diameter of 5 mm. It is particularly advantageous if one uses the green waste on a fiber size of 0.05 to 0.2 mm. in particular about 0.1 mm. chopping or grinding to obtain a powdered product which is then dried and pelletized. The pellets obtained have a high water absorption capacity of about 100 g of water per 10 g and are therefore versatile, e.g. as bedding for livestock and / or pets, such as horses, chickens, cats, etc., but also for other purposes.

The water uptake ability is further improved if water-binding agents, in particular polyacrylamides, are added to the chopped or ground green waste before pelletizing. Gel-forming, cross-linked polyacrylamide granules, such as those under the following, are exemplified by particularly advantageous additives. brand name "Polywater-Aqua-Plus" available from Polyplant-Consulting Export-Import GmbH, Kalkar. This granulate can absorb and bind 400 ml of water per g.

. The pellets manufactured in this way can be used particularly advantageously as additives for sewage sludge, from which a considerable moisture content is extracted in this way. The sewage sludge can then be applied to agricultural land in a known manner. In this case it is advantageous if odor-inhibiting agents are additionally added to the sewage sludge.

Alternatively, in a further advantageous embodiment of the invention, plants can be grown on the sewage sludge mixed with said pellets and optionally with odor-inhibiting additives and, after harvesting the plants, the remaining residue of the sewage sludge is discharged. As examples of such additives are activated carbon. coal dust, lava rock flour, quicklime, chalk and / or called odor masking synthetic chemical compounds.

In addition, it is advantageous if the sewage sludge mixed with the said pellets is mixed with compost, in particular approximately in equal parts, and only then let the plants grow thereon.

For an economical processing of sewage sludge, such as this occurs at sewage treatment plants, it is proposed that a plant substrate, which in particular consists of compost, is planted with rhizome-forming plants and liquid sewage sludge is applied thereon at short intervals. The water content of the sewage sludge largely evaporates and the solid components are consumed by the growth of the 20 plants.

In this case, it is an advantage if the roof of a greenhouse is installed above the plant substrate, which prevents the liquid content from increasing by rain and other precipitations. A further advantage lies in maintaining a relatively high temperature, even in winter, so that evaporation and thereby thickening of the sewage sludge is promoted, without the need for cumbersome filter presses. In order to collect the condensation water, the roof of the greenhouse can contain a condensation water gutter in its lower part, so that the collected water can be used for watering other plants. In this embodiment of the invention, liquid sewage sludge is applied repeatedly, which rot for about 70 to 90¾. After about 10 years, the non-rotatable residues, e.g. stones, are dredged. Further data can be found in the following example III.

Some tests, in which the feasibility and advantages of the method according to the invention are demonstrated, are described in more detail below.

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Example I

A 1.50 m high bed with biological waste, which was covered with mother soil, was planted with polygonum in May. In November of the same 5 years, the bed had collapsed to a height of 0.80 m.

Example II

In a greenhouse test, a conventional flower pot 10 with a diameter of 14 cm was filled with biological waste in the spring and planted with reed (pfragmidis). In the fall, the pot contained virtually no biological waste. but only root material.

Example III

15

Liquid sewage sludge according to the invention was processed in this test. A planting pit was covered with plastic foil. The pit had a surface of 700 m2 and a height of the slope of 1.3 m. On the ground surface, compost is applied as a plant base in a thickness of 0.40 m and planted with rhizome-forming plants, using 5 plants per m2 . Liquid sewage sludge with a height of about 8 cm each is applied to the surface thus prepared at intervals of 2 to 3 weeks.

Approximately 750 1 liquid sewage sludge per mz is applied in approximately 12 work steps per year. With a surface area of 700 m2, this corresponds to an amount of approximately 525 tons of liquid sewage sludge per year. The application of the liquid sewage sludge increases the layer. On the other hand, because the plant layer decreases approximately by the same value due to natural rotting, the thickness of the plant substrate does not increase substantially net and remains at approximately 40 cm.

] 1010703

Claims (20)

Method for processing biological waste, in particular of contaminated compost, of biological waste material 5 generated in the food industry, of sewage sludge and the like, and for cleaning in particular of heavy metals or otherwise contaminated soil , whereby first a first layer of the biological waste resp. apply the contaminated soil to a surface, let plants grow on this layer, harvest the 10 plants, then a second layer of the biological waste resp. apply the contaminated soil to the previous layer and treat it in the same way, whereby the method is optionally repeated once or several times and finally the residual residual of the biological waste resp. the soil processed, with the characteristic. That rhizome-forming plants are used and that the thickness of the second layer is measured so that the rhymes of the plants can grow through this second layer. 2. Method according to claim 1, characterized in that upon application of the biological waste resp. the contaminated soil creates and leaves traces of the usual width for tractors. 3. A method according to any one of the preceding claims, characterized in that plants are grown on the contaminated soil, which selectively pollute the pollutants, in particular heavy metals, to a smaller extent than the other substances when they absorb nutrients. into the ground. Method according to claim 3, characterized in that buckwheat powder is used as plants for cleaning soil contaminated with heavy metals. applies horsetail and / or polygonum. A method according to any one of the preceding claims, characterized in that the plants are annuals. A method according to any one of claims 1.2 and 5, characterized. that as plants polygonum, reed. iris, sunflower, bamboo, 1010703 pampas grass and / or C4 plants. Method according to claim 5 or 6, characterized in that the thickness of the layers is 0.3 to 1 m. 5 Method according to any one of claims 5 to 7, characterized in that sand and / or a sand-like material, in particular finely ground construction waste, is added to the biological waste and the layers are at least 1 m thick. Method according to any one of the preceding claims, characterized in. that 5 to 10 superimposed layers are applied and only then the remaining rest of the biological waste resp. the contaminated soil is processed. 15 Method according to any one of the preceding claims, characterized in. that on each layer of the biological waste a layer of earth, in particular mother soil, is applied, which preferably has a thickness of 5 to 10 cm. 20 Method according to any one of the preceding claims, characterized in. that before processing the remaining rest of the biological waste resp. the contaminated soil has removed the root material present therein, in particular by sieving and, in particular, as new planting material or by composting, reused. Method according to any one of the preceding claims, characterized in. that the green waste obtained after harvesting the plants is ground or chopped, optionally dried, in particular to a residual moisture content of 8 to 10% by weight or less, and used as litter for livestock and / or pets. Method according to any one of claims 1 to 11. characterized in. that the green waste obtained after harvesting the plants and / or green waste obtained from other sources is ground or chopped, dried H, in particular to a residual moisture content of 8 to 10; weight percent or less, and pressed into pellets, which are typically about 1 cm in length and 5 mm in diameter. 1010703 Method according to claim 12 or 13. characterized in that the green waste is chopped or milled on a fiber size of 0.05 to 0.2 mm, in particular about 0.1 mm. Method according to claim 13 or 14, characterized in that water-binding agents, in particular polyacrylamides, are attached to the chopped or ground green waste before pelletizing. adds. 16. Use of the pellets produced according to any one of claims 13 to 15 as an additive for sewage sludge. Use according to the preceding claim, characterized in that odor-inhibiting agents are additionally added to the sewage sludge. 15 Method according to any one of claims 13 to 17, characterized in that plants are grown on the sewage sludge mixed with said pellets and optionally with odor-inhibiting additives and the remaining residue of the sewage sludge is processed after harvesting the plants. . 19. Process according to the preceding claim, characterized in that the sewage sludge mixed with said pellets is mixed with compost, in particular in approximately equal parts, and only then the plants are grown thereon. A method according to any one of the preceding claims, characterized in. that a plant substrate, which in particular consists of compost, is planted with rhizome-forming plants and liquid purification sludge is applied thereon at short intervals. 1010703