DE1592800A1 - Process for composting waste materials - Google Patents

Description

Method of Composting Waste Materials The invention relates to relying on a method of composting; of stored in a rent or containers Waste materials with the addition of water or aqueous liquid, e.g. liquid manure, sewage, Sewage sludge or the like and with aeration, e.g. by means of air, an oxygen mixture or a gas containing free oxygen, and stabilization of the ripened Compost.

Microbiological processes take place during composting which the organic substances are converted. The goal of composting is it, the waste materials through a controlled bacteriological rotting process to convert as little loss of organic matter as possible into an earthy product, to return it to nature's cycle of matter as a soil improver. Such a rotting process is a process in the aerobic area, i.e. in the presence of oxygen, with which no stink gases are generated. The material must first must be sanitized, i.e. any pathogens that may be present in the waste must be or the like. Be destroyed. A perfect sanitation is achieved by that metabolic products of bacteria and fungi under temperatures approximately between Act on the waste for a longer period of time at 55o and 60o Celsius. Included weed seeds are also destroyed. At a temperature higher than about 70o - At 750C the bacterial activity is at least strongly reduced and oxidation processes occur that do not yell in the direction of the desired bacterial rotting. Under ;: tabilisivriziat; is understood a Vorgiuig, in which the waste material through -Dehydration can be rialtbar, i.e. la @; erf: ihig is made.

It is known to control such a rotting process in reed composting in that the windrows are rewetted several times, usually two to four times during the composting period. A ventilation unit automatically finds its way; of the material. The repositioning must be carried out according to a schedule. Unfavorable weather conditions can have a very disruptive effect, such as an undesirable anaerobic course of the composting process. This results in inadequate sanitation of the material, uneven decomposition and remodeling of the components of the waste, unpleasant odors and a significant delay in the ripening of the compost. It has also been found in practice that reliable control of the composting process is no longer guaranteed, especially with increasing pile height. For reasons of economy - in order to save space - the highest possible rent is very desirable. Another very decisive disadvantage of this well-known pile composting method is that the ripening takes a very long time over many months. This means, however, that the space requirement, for example when using composting for the removal or conversion of household waste in a community, is very large for this reason too, and thus the investment and operating costs for such a system are relatively very high. A method is also known in which the waste in so-called fermentation cells, which are open at the top, is simultaneously and continuously sprinkled with water and permeated with air in such a way that the temperature of the material is constantly kept at around 65 to 700C and, after the pre-fermentation has ended, the sprinkling first reduced and then completely; is set while the air flow is continued until a dry hatred is achieved (DRP 700737). Composting using this method is also very slow. Ptv-ch the permanent series: ir = lurii -% v is the training ahead t'ia @; eri_c @ nt: rclnr: idend disturbed. However, tiles are an essential ti rather part of a; 3 so-called living construction, ' d. ic. a mechanical stabilization of the rent material. purpose this mechanical feat by living construction is a times the evaluation-a _ as large as possible pore volume for Iec:; iaeren storage of water and devil in rent .and : another allows the greater mechanical strength in an economical way. to set up higher rents without that- (read material on the bottom of the, rivet too, very squeezed, 7. .: ird. : t is also known to accelerate the maturation of a. such rent from the outside. : aif lead that for development. Multiplication urid. i.ii.activity of the beneficial bacteria at an optimal temperature in the rent is retained and the rent to avoid ti.a. , of umbrella losses and dehydration by the wind a porous insulating sheath made of straw od. Like. And over it with rainproof roofing felt-protect from the sun-Ude-r Od. Like. Is covered, with the preservation of the optimal Moisture content of the bid. Water or diluted liquid manure Other fertilizers alone or in a mixture with bacterial crops on the whole length of the rent, however - under the man- f.el d-ersel ben be fed. This should - preferably also - the air periodically or continuously into the interior of the pile be blown to .stagnant. Gases from rent from inside. to displace outwards through the porous jacket. (DBP 1-013 300 ) . Composting according to this method is also still going on Long. Apart from the disadvantages already mentioned, one With continuous sprinkling, the supply of heat is very costly. :: pielig.- The application of an insulating jacket is very : stii.ridlicli and time consuming and at least complicates the removal the worn nose. The addition of bacterial cultures is. make today's knowledge at least very problematic Jurid .in 'usually superfluous because the bacteria are in the correct Develop the environment yourself. The invention is based on the object of providing a method for composting waste materials stored in a rent or containers with the addition of water or aqueous liquid, such as liquid manure, sewage, sewage sludge or the like. and to provide the mixture by aeration, for example by means of air, an atmospheric oxygen or a free oxygen-containing gas, and stabilization of the mature compost, ches WEL the disadvantages of the known methods has not and in which in particular the hygienizing and composting time largely independent of climatic conditions and as short as possible to cover the cost of the space required for the rents or the like. to be kept small, and where the rents do not need to be repositioned. In addition, the method is intended to achieve as extensive a living structure as possible in the material . This object is achieved in that according to the invention periodically approximated the tem- perature of the waste material by intermittently supplying the liquid and by each subsequent reduction of the water content by ventilation alternately between a mesophilic for the bacteria area as possible below 45o C, but not below 100 C and at least until is controlled to the respective maximum achievable in the thermophilic temperature range , but not above 750 C. The optimum viability of mesophilic bacteria is mainly below 459 C, while the optimum life activity of thermophilic bacteria is predominantly above 45o C. The addition of water and ventilation thus takes place according to the invention such that the temperature is always above between these two areas and below commute from 45o C, namely within one optimal functioning of all for composting beneficial bacteria and fungi promoting Gesamttemperaturbereches between about 250 and 7500 .

Each of the two essential groups of bacteria are thus in the optimal development conditions for each period are offered. Included the temperatures pass through the two temperature ranges above and below 450C multiple. This and the controlled changing water content in the material between full water capacity, i.e. between the maximum amount of water that it is able to fully absorb at all, and consequently a reduced water content can the rotting time - as tests have shown - compared to the known methods can be shortened significantly. So it will be in a natural process to a certain extent Meaning simulates conditions as they exist in the tropics, where, as is well known, organic Fabrics rot the fastest. Due to the periodic addition of liquid an undesirable rise in temperatures inside the windrow to over 750C largely prevented. The temperatures drop after the addition of liquid a value in the mesophilic temperature range and then rise within a few days again on: A transfer of the rent is not necessary with this procedure. It also takes place at the beginning of the composting process due to the strong ventilation of the material kept at full water capacity within the first few days rapid decomposition and conversion of the easily decomposable and convertible organic substances take place. Here the water content of the rent decreases and it takes place due to an occurring relatively strong fungal growth, an extensive living structure, i.e. a safeguard the pore volume for ventilation and water drainage as well as mechanical consolidation of the rental material. To a strong live construction at the beginning of the composting To ensure, it is advantageous if between the first and second windrow irrigation a period of. at least two days.

A drop in the water content below 25% is the microbiological one Activity of the bacteria is too low or too 1; suddenly stops, should expediently during composting; iii13 this value should be used when aerating not undercut.

It can be advantageous in a further development of the method according to the invention be to add nutrients or fertilizers known per se to the liquid. Included the addition can be chosen so that the liquid is either alkaline or is sour or it can also alternate and sour in a certain rhythm can be made alkaline. For an acidic liquid, e.g. superphosphate is used as an additive and for an alkaline e.g. ammonia.

Towards the end of the composting process, i.e. after about three up to four weeks, it is advantageous to stop adding fluids and by blowing in as dry a possibly heated gas as possible, e.g. 8. warmer Air to bring the water content to a value below 20ö. This will make the material stabilized and therefore storable.

The method according to the invention is explained in more detail below with reference to some exemplary diagrams shown in the drawing for the treatment of compostable material stored in a pile. The diagrams each show the time in days d as the abscissa in: Fig. 1 the amount of water supplied in each case in liters per m3 of material, Fig. 2 the amount of air G supplied in liters per second and m3 of material, Fig. 3 the respective water content of the material in percent by weight and FIG. 4 the mean temperature profile of the material in ooelsius. As shown in Fig. 1, while the pile is being set up, i.e. on the first day, the material is supplied with an amount of water 5 corresponding to the full water capacity within a period of h of up to a few hours, while at the same time, as in curve 6 , Fig. 2, the ventilation of the pile begins continuously. The curve ? in Fig. 3 shows the respective full water capacity of the material, which decreases during the composting process with increasing maturation of the material. Due to the water supply and the simultaneous ventilation, the microbiological activity of the bacteria is stimulated, which results in a strong heating of the material, as curve 8 in FIG. 4 shows in the range up to the 5th day. The temperature rises steeply at first and then a little more slowly from the meaophilic temperature range _. in the thermophilic temperature range. When it reaches about 700 to 750C, in order to prevent the temperature from rising further (in the present case on the 5th day), an amount of water 5 '(FIG. 1) is again added. In the interest of an initially as intensive as possible living construction, there should be a period of at least two days between the first two waterings . There are therefore no concerns about letting the temperature rise a little above 750 in the first period if 50C should be reached before the second day. After adding the amount of water 5 ', which is somewhat lower because of the already slightly less full water capacity (Fig. 3, curve?), and after further aeration, the temperature initially drops quickly again to the mesophilic range (Pig. 4, curve 8) and then rises again after the end of irrigation, but with constant ventilation, until after a few days - in this case again after 5 days - it has reached the temperature peak at around ? 00C, whereupon the cooling and heating process in the same Way begins anew. With increasing heating of the water content of the material decreases due to the further aeration of How-off to a minimum value, which, however, should not be less than 25%. (Fig. 3, curve 9).

With the periodic repetition of the water supply, the decrease discontinuously respectively supplied amounts of water 5.5 ', 5 "usr. corresponding to the decreasing full kaaser capacity, until finally none at all More water is supplied, as happens in the present case after the 21st day. In doing so, the amount of ventilation decreases - roughly correspondingly. growing What salary - also to a certain extent from (curve part 109 Fig. 2), but will Increased again approximately within the last third of the maturation period (part of the curve 11) and preferably heated in order to stabilize the material Bringing the water content at the end of composting to a value below 20% (Curve 9, Fig. 3). At the latest after about half of the composting time is ilygienization of the material is completed and one'have then a material that is already can be used as a soil covering agent (mulch). So-called mature compost is received after about 30 days.

As the composition of the waste materials and the climatic conditions are very different, are subject to the numerical values given only by way of example certain tolerances. Such values, in particular those of the full water capacity, the duration of the temperature rise up to about 700C etc., must be on a case-by-case basis, d.ii. must be empirically determined separately for each composting plant.

Claims (9)

Claims 1. A method for composting waste materials stored in a rent or in containers with the addition of water or aqueous liquid, such as manure, sewage, sewage sludge or the like. and by aeration, for example by means of air, a mixture of atmospheric oxygen or a gas containing free oxygen and stabilization of the matured compost, characterized in that the temperature of the waste material is periodically alternated between one for the bacteria by discontinuous supply of the liquid and each subsequent reduction in the water content by ventilation mesophilic range as far as possible below 45o C, but not below 100 C and at least approximately up to the maximum achievable maximum in the thermophilic temperature range, but not above 75o C. 2. The method according to claim 1, characterized in that the liquid in each case until reaching at least approximately the full water capacity of the waste material is fed. 3. The method according to claim 1 and 2, characterized by such Control of the fluid supply and ventilation that the periodic temperature peaks from the start of composting to the end of it, at most an initially constant one High and then have a substantially falling "tendency. 4: Procedure after a of claims 1 to 3, characterized in that between the first and second Rent irrigation is a period of at least two days. 5. Procedure according to one of claims 1 to 4, characterized in that during composting When ventilating the waste material, the water content does not fall below 25%. 6th Method according to one of Claims 1 to 5, characterized in that the liquid known nutrients or fertilizers are added. 7. Procedure for a of claims 1 - 6, characterized in that the supplied in each period Liquid is consistently acidic or alkaline. B. Method according to one of the Claims 1 to 6, characterized in that the liquid supplied in each case is acidic and alkaline in a certain rhythm. 9. Procedure according to one of claims 1 to 8, characterized in that towards the end of the composting process the addition of liquid is stopped and by blowing one as possible dry gas, preferably drier teuft, the water content to a value below 20% is brought.