DE2311397C2 - Composting process - Google Patents

Description

The invention relates to a composting process in which the material deposited is oxygen and / or water is supplied.

The oxygen required for composting can be stored in cells and chambers at low levels or free debris can be taken from the surrounding air without the need for special facilities are required for ventilation. The disadvantages of these naturally ventilated systems are relative high space requirement and usually insufficient self-heating due to insufficient bulk volume or due to a surface that is too large, which in turn results in high heat losses. Around To avoid this, it is also known to pour as high as possible and either pour more often implement or ventilate them artificially. In this case and in the following, both the blowing-in is under ventilation as well as sucking in air.

Since z. B. in the composting of a garbage-sewage sludge mixture There are always very large amounts of material to be composted to cover large areas with heaps, which depending on the material accumulated continuously and after When the composting is completed, it will be removed to make room for new material. It is known, to continuously supply air to such heaps (German Patent 805 044). This causes but usually undesirably large temperature differences between the top and bottom layers as well as one undesirably strong cooling and / or harmful dehydration during the actual composting and disinfection phase.

It is also known to add air to the material in interrupted pokes, wooei die Breaks are dimensioned so that the temperature in

“O is the same in all layers of the compost raw material and the oxygen content in the exhaust air does not drop below 10 percent by volume (German interpretation 1592729). So only the temperature should be used here and moisture in all layers of the compost raw material

is rials are largely kept the same. There is there is still the possibility that the temperature will drop if the ventilation is too intensive or that Material dries out.

As is known, the temperature rises at the beginning of the

jo composting in a so-called start-up time within a few days to a value, the amount of which depends essentially on the composition of the material depends. However, for optimal composting, it should always be as high as possible Temperature value should be aimed for, although towards the end of the ripening process after about 10 weeks only significantly lower values can be achieved than at the beginning. During the temperature development In the approx. 2 to 3 day start-up period, which can hardly be influenced, there is the possibility of the second longer phase to influence the temperature. However, one has no theoretical measure for that Amount of oxygen, which according to the material and progress of the composting process (age) for optimal composting is required. There is also the risk of excessive ventilation and the associated drying out of the material instead of an increase in temperature, or at least essentially maintaining the existing temperature, this in an undesirable Dimensions drop sharply and, as a result, the material for further aerobic composting can be unsuitable ..

The invention is based on the object of specifying a method which is particularly suitable for Composting large quantities - for an at least approximately optimal composting process - Controlled oxygen supply enabled in the phase following the start-up time and at The lowest possible energy expenditure, in a short time and with the best possible use of what is available Floor area, perfect ripening achieved.

This problem is solved according to the invention in that a material temperature of at least 5 40 ° C, which occurs after a relatively short time compared to the start of composting, serves as a guide value for the start of an automated temperature control, which is below a specified value T _L of about 4 to 10 ° C aeration of the material over a time x, and below this by a value T _w > T _L of about 7 to 20 ° C trigger a moistening of the material over a time x ₂ , and that after a reaction time x _} from the end of the respective aeration · Or the humidification period, a readjustment takes place to the then existing temperature as a new guide value.

The ventilation preferably takes place in each case

intermittently. The method according to the invention makes it possible to keep the material in an essentially optimal condition for composting and thus to keep the energy expenditure for ventilation and humidification to a minimum. In addition, this results in a short storage time, which is again advantageous in terms of low space requirements affects. The amount of the values to be specified, such as B. with intermittent ventilation the respective duty cycle of the ventilation and the breaks or the values for T _L , T _w , X ₁ , X ₂ etc. depend on the location (climate), material properties etc. and can easily be empirically determined by the person skilled in the art be adjusted. Since the material quality in such a composting plant is generally essentially constant for a specific location, it is to be expected that the values once established can be maintained at least for a longer period of time.

The ratio of ventilation switching on and the following pause is preferably about 1: 3. A ventilation period Jc ₁ can e.g. B. 1 or 2 hours, but also a multiple of this time. If suitable devices are available to suck or blow very large amounts of air per unit of time through the heaped material, then an intensive short, uninterrupted ventilation of about 5 to 30 minutes can be sufficient. The triggering of the automatic control should advantageously only take place when the temperature of the material has risen to at least 40 ° C. during the start-up time.

If the material has become too dry as a result of the ventilation and instead of the desired rise in temperature there is a further drop in temperature, after the temperature falls below the value T _w below the reference value, the material is humidified instead of ventilation. This moistening period should preferably last until at least 10 liters of water per m ^{3 of} material have been added. The duration depends on the amount of material to be treated and the amount of water per unit of time that is to be added. The latter in turn is essentially dependent on the respective absorption capacity of the material. On average, a fluid intake of around 1 liter per m ³ and minute can be expected, which would correspond to a value x ₂ of around 10 minutes.

The value for X ₃ must be so large that if there is a further drop in the material _{temperature after an aeration period X 1} , the temperature T _w below the respective reference value is reached in any case, in order to trigger _{an irrigation period Jr 2.} It depends on the age of the material and its water content. He can z. B. be specified as an empirically determined fixed value and remain constant during the entire composting process or be varied in the successive composting periods after each readjustment of the reference value according to a certain program.

According to a very advantageous development of the invention, an optimal value for the reaction time X ₃ is obtained in that the length of this time is determined by the maximum of the temperature curve T - f (t) of the material following the ventilation or humidification period, ie if dj_ _ q

will. This point can easily be detected by a suitable electronic circuit. Created at the same time represents the new guideline value for the following control process.

The method according to the invention is explained in more detail using a diagram that is not to scale.

In the diagram, the time t is plotted on the abscissa and the temperature T on the ordinate.

ίο The dashed curve T = / (*) of the material temperature rises after a relatively short start-up time A (e.g. after two days) to a value T ", which should be around 60 ° C. At this point in time the automatic control procedure according to

S ¹ a of the invention. When the value 7 * j is reached as the first reference value, the SoU value curves S _L1 and S _wl running parallel to the abscissa and representing constant values are established, of which S _{L1 is} around the value T _L , e.g. 5 "C, below T ₁ and S _wl around the

»° Value T _w , for example 10 ° C, is below T ₁ . The actual material temperature curve (actual curve) T = f (i) has a decreasing tendency from T ₁ and touches after the time 'X ₀ , which is essentially determined by the material composition and is not programmed, the curve S _LV . z. B. a fan triggered, which in the present example in a fixed rhythm intermittently over a fixed time x "z. B. 3 hours, the material is ventilated and thus supplies oxygen. The ventilation rhythm

3 «mus can z. B. be set in such a way that alternating 15 minutes of ventilation followed by a 45-minute break. Due to the supply of oxygen, the temperature T in the material begins to rise again. After the ventilation period has ended, the material remains during the reaction time X ₃ , e.g. B. during an empirically determined time of one day, at rest. During this time X ₃ , the temperature continues to rise until, at the end of the reaction time x ₃ , it has reached temperature T ₂ , which in the present example is greater than T ₁ . The process sequence is now readjusted to the new temperature value T ₂ as a guide value and the new setpoint curves S _L2 and S _W2 are established, which in turn are below the guide value T ₂ by the value T _L or T _w . Composting period 2 runs in the same way as composting period 1, only the non-programmed times X ₀ are each different, depending on how quickly the temperature of the material falls and reaches the setpoint curve S _L2 . After the ventilation period 2, in the example shown, the temperature rises _{slightly again during the reaction time x 3} and reaches the value T ₃ as a new guide value, which at the same time represents a maximum; then afterwards it drops again relatively quickly and reaches the 5 _L3 curve _{after the time x 0.} Despite the onset of ventilation, the temperature continues to drop because the material is too dry. However, this temperature drop does not yet reach the setpoint S _W3 for triggering the irrigation during the aeration time χ ι, but this value is only reached during the reaction time x ₃ following the aeration time x, which is interrupted when the irrigation starts, ie not via the the entire programmed duration expires.

The water supply gives the microorganisms the opportunity to take up oxygen again, and the temperature rises noticeably again, even during the end of the irrigation

serungsperiode X ₂ newly onset of reaction time x _3, and reaches the end of this time the new guide value-forming temperature value T. ₄ The temperature begins to drop again in this fourth composting period, and in the example shown relatively quickly, and the aeration is switched on after the value falls below S _LA. Again, the material has dried out too much - for example due to a dry period in summer - but now sinks so quickly that it falls below the setpoint S _{W4 within the programmed ventilation time Jt 1.} At this point the ventilation period is already interrupted and the ventilation period Jt ₂ begins instead. The temperature begins to rise again and reaches the new reference value T ₅ after the end of the reaction time x _{3 following this humidification period jc 2} .

The next composting periods can

then either again similar to periods 1 and 2 only with ventilation or if the material is too dry has become, similar to the described periods 3

or 4 drain with irrigation for a total of until after a few weeks

ίο material essentially completely composted, i.e. has matured.

The invention is equally applicable to such Composting processes can be used in which the material is treated in rotating drums or in so-called composting towers.

For this! 'Sheet of drawings

Claims (5)

Patent claims: 1. Composting process, in which the heaped material oxygen and / or water is supplied, characterized in that a material temperature of at least 40 ° C, which is established after the start of composting after a relatively short time, serves as a guide value for the start of an automated temperature control a value T _L of about 4 to 10 ° C. triggers aeration of the material over a time Jt ₁ and below this by a value T _w > T _L of about 7 to 20 ° C. triggering moistening of the material over a time X ₂ , and that after a reaction time Jt ₃ from the end of the respective ventilation or humidification period there is a readjustment to the then existing temperature as a new guide value. 2. The method according to claim 1, characterized in that the ventilation during the ventilation period occurs intermittently. 3. The method according to claim 2, characterized in that the ratio between the The duration of each ventilation activation and the following pause is approximately 1: 3. 4. The method according to any one of claims 1 to 3, characterized in that at least 10 liters of water per m ^{3 of} material are supplied during the moistening period. 5. The method according to any one of claims 1 to 4, characterized in that the length of the reaction time is determined by the maximum of the temperature curve T = / (<) of the material following the ventilation or humidification period.