DE8707175U1 - Device for composting organic waste - Google Patents

Description

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Description

The invention relates to a device for composting organic waste with a compost container forming a rotting chamber with a filling opening arranged at one end for filling in the organic waste and a removal opening provided at the opposite end for removing the compost and a ventilation device arranged in the rotting chamber.

A device of the type mentioned is known from DE-PS 25 08 321 and consists of a horizontally or inclined rotating cylinder for rapid composting of organic waste materials/which has inlet and outlet elements in each end of the cylinder. A pipe with openings for the air supply is provided running in the middle of the cylinder’s lengthwise direction, while an exhaust gas extraction device is arranged in the upper part of the cylinder, which comprises several pipes running in the cylinder’s lengthwise direction and having openings. The pipe for the air supply and the pipes for the extraction device and, if necessary, a water supply device serve in the known device to increase the effectiveness of the microorganisms required in the composting process by improving their environmental conditions. The known device, however, is relatively complex in construction and can only be used economically in stationary operation.

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The purchase costs for the known device are very high and the handling of the device during operation is cumbersome. Furthermore, with the known device it cannot be ruled out that dry nests will form in the rotting mass due to a lack of homogeneous fine ventilation with oxygen or air.

DE-OS 31 04 769 describes a method and device for generating usable heat by rapid decomposition or composting of plant waste and stable manure. In the known method, the material intended for decomposition is first roughly chopped before being fed into a reactor and is circulated through various chambers inside the reactor while constantly being mixed, with the material being aerated and re-chopped during this cycle. The known device or reactor consists of a horizontal container with a filling opening and a stirring screw arranged inside the container that rotates around a horizontal axis, as well as a removal opening at the end of the composting cycle. This known device also requires high acquisition costs and is prone to malfunctions and difficult to operate due to the numerous conveyor devices. In addition, at least one electric drive is necessary, which entails additional operating costs and the proximity of an electrical connection. The exploitation or partial exploitation of the

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Furthermore, the removal of the rotting heat generated during positioning is only possible with mechanical aids, which also reduces the area of application of the known device.

The object of the present invention is to create a composting device of the type mentioned at the beginning, which is mobile and can be used directly at the places where organic waste is generated, which is easy to handle and inexpensive to purchase and which enables optimal rotting while avoiding anaerobic zones in the rotting chamber and the utilization of the heat and biological gases generated during the composting process in a simple manner without the supply of additional energy.

This object is achieved according to the invention in that the compost container is provided with a holding frame for mobile transport and vertical or inclined positioning of the compost container and in that the ventilation device extends essentially over the entire length of the rotting chamber and/or the bottom of the compost container and is connected to a compressed air pump or a blower.

The solution according to the invention creates a device that can be used in a mobile manner at the places where the raw material for composting is produced, guarantees the supply of oxygen to the microorganisms due to the central forced ventilation and thus avoids the formation of anaerobic zones, improves the rotting process by preheating

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of the raw material with the gases and water vapours arising in the warmest rotting part, which collect in the ventilation pipe and escape into the rotting mass in the upper third of the rotting chamber, whereby the warm water vapour contains microorganisms, ^T .omit the rotting material and the composting process is quickly initiated, creates the prerequisite for the release of radiant heat to a greenhouse part that can be connected to the device,

whereby the discharge and release of the generated

biological gases, mainly carbon dioxide, into the plant area of the greenhouse section and thus achieves high plant growth rates

&igr;, while in winter operation the composting

\ device for the production of green plants, in particular

especially of kitchen herbs, etc., without additional energy, and ensures that no additional energy needs to be supplied, since the forced ventilation of the rotting mass takes place without mechanical drives.

Advantageous embodiments of the inventive solution can be found in the features of the subclaims.

The idea underlying the invention will be explained in more detail using an embodiment shown in the drawing. It shows:

Fig. 1 a longitudinal section through a mobile composting device with manually operated shredding device;

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Fig. 2 is a schematic diagram for explaining the composting process in a composting device according to Fig. 1;

Fig. 3 shows a longitudinal section through a simplified composting container;

Fig. 4 a cross section through the ^composting container according to Fig. 5 3

Fig. 5 a longitudinal section through a raised bed composting device;

Fig. 6 a cross-section through the rotting chamber of the raised bed composting device according to Fig. 5;

Fig. 7 a longitudinal section through a rapid composting device with conveyor screw and

Fig. 8 is a plan view of a part of the conveyor screw of the device according to Fig. 7.

The longitudinal section through a mobile composting device shown in Fig. 1 shows a compost container 1 in the form of a tube or a drawer made of, for example, polyurethane rigid foam, which is available as a standard part and is provided with a bacteria-resistant plastic coating on the inside. "The compost container 1 encloses a rotting chamber with an upper filling opening 11 and a lower removal opening 12 and is provided on its outer wall with a sheet steel or aluminum cladding 7 and mounted on a holding frame 6, on which wheels 9 are arranged in the lower area, while in the upper area near the inlet

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filling opening 1.1 one or more handles 10 are provided.

The removal opening 12 is formed by a removal flap 5 which is fixed about a horizontal axis 51. It closes a removal box 120 which is attached to the compost container 1 and is constructed in such a way that the composting device has a secure stand during stationary operation. It has a slanted wall 121 and a horizontal base plate 122 which ensures that it rests on the ground during stationary operation.

The center of gravity of the entire composting device is designed in such a way that with a slight tilting of the composting device, the removal body base 122 is raised and the wheels 9 carry the composting container 1, so that the composting device can be transported to different locations.

The filling flap 4, which is also provided with a strong thermal insulation layer, is attached to the highest point of the rotting chamber 2, while - as described above - the removal flap 5 is attached to the lowest point of the rotting chamber 2 and, through its arrangement on the front of the compost container 1 in conjunction with a handle 23 attached on the same side for opening the filling flap 4, ensures easy operation of the composting device.

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In the middle of the rotting chamber 2, a ventilation device 3 is provided, which extends over the entire length of the rotting chamber. A compressed air hose 17 is attached to its lower end, which can be protruded, for example, from a side wall of the compost bin.

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uaxuc£.s &khgr; ncLauoyciuiiJ-i. uiiu nix u CXIiCi. riuuiiuiuuaj.ui.c- foot pump 8 is connected/ with which an overpressure of up to tu 2 bar can be generated. With the help of this ventilation device 3, sufficient ventilation of the rotting mass in the rotting chamber 2 and optimum heat distribution are possible.

The ventilation device 3 can optionally consist of a plastic pipe, preferably a PVC pipe, which is provided with longitudinal slots evenly distributed around the circumference and along the length. Alternatively, the ventilation device 3 can consist of a PVC pipe with holes and a thin rubber covering, which is also provided with holes and/or slots* Another possibility is to form the ventilation device from flat hoses with finely distributed holes or wedge-shaped slots, which open from the inside when there is excess pressure and close again when the air pressure is normal.

Finally, the ventilation device 3 can consist of porous plastic or stone pipes which allow gases to pass through on both sides but prevent the ingress of water.

The centrally located ventilation system

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3 and the many microscopically small openings in the ventilation system ensure that the microorganisms are supplied with sufficient air/oxygen over the entire length of the rotting chamber 2 and that anaerobic zones cannot develop.

In the area of the upper third of the compost container 1, a thermometer 19 with its temperature sensor protrudes into the rotting chamber 2 and can be read from the outside is arranged.

A shredding device can also be arranged in an insert of the filling flap 4, which consists of a knife 14 provided with a handle 16 and a plate 15. By moving the knife 14, which is held on the handle 16 and can be pivoted about an axis 24, up and down, coarse rotting material, such as twigs or branches, can be shredded or shredded before being filled into the rotting chamber 2.

The operation and functional principle of the composting device according to Fig. 1 will be explained in more detail using the schematic diagram shown in Fig. 2.

Organic material for composting in the composting device according to Fig. 1 includes garden waste, such as leaves from fruit trees, birch or oak, hedge clippings, branches, clippings from garden flowers, lawn clippings, vegetable waste and manure from small animals such as rabbits and chickens, kitchen waste such as vegetable scraps, potato peelings, residues from coffee and tea filters, onion

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peels, chives and fruit residues as well as unprinted paper and cardboard without coating or labeling. The organic waste, which may have been previously shredded using the shredding device, is fed into the rotting chamber 2 by lifting the filling flap 4, whereby the shredding and homogeneous mixing of the organic

Waste prerequisite for good composting j.

In addition, a rapid composting 1

agents such as commercially available rotting accelerators can be added to the % rotting chamber 2. Il

After the organic waste has been filled into the rotting chamber 2, after about three days the high-pressure air foot pump 8 is operated several times every second to third day, whereby the thermometer 19 shows how the rotting temperature rises to a temperature of +78'C within a few days due to the strong thermal insulation of the compost container 1. The ventilation device 3 and the rotting process produce gases and water vapors which collect in the ventilation device 3 and penetrate the raw mass in the upper third of the rotting chamber, thereby preheating the raw material. The warm water vapor contains microorganisms which inoculate the raw material and initiate the composting process in a few hours. The following zones are formed:

a) Feed zone A with preheating of the rotting material by the heat rising in the ventilation device 3, in which the composting process can be accelerated by the addition of rapid composting agents. This zone has a temperature of approx. 10 - 20°C, i

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b) The introduction zone A is followed by the dynamic wetting zone B with a maximum temperature of up to 80*C.

c) This is followed by the material reduction zone C with a temperature that drops from approx. 40°C to approx. 25°C.

d) The lowest zone D characterizes the area of residence of earthworms, reproduction of earthworms and rotting with a temperature that drops from approx. 25°C to approx. 10°C.

As a result of the intensive rotting process, the rotting material collapses after about two weeks, so that raw material can be refilled via the filling opening 11. Advantageously, after about three weeks, about 20% of the rotted material should be removed via the removal opening 12 and refilled into the rotting chamber 2 via the filling opening 11, so that continuous operation is initiated.

In continuous operation, shredded raw material can be continuously fed into the rotting chamber 2 via the filling opening 11, depending on the amount, whereby the high-pressure air pump 8 is activated to supply air during refilling.

Hot composting or rapid decomposition ensures that garden and kitchen waste

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with their usable, organic components, are recycled in an environmentally friendly way, whereby the garden and kitchen waste is freed from parasites and germs as a result of hot composting and the relative germination capacity of weed seeds is completely reduced.

In Fig. 3, a compost container that is simplified compared to the compost container according to Fig. 1 is shown in longitudinal section, where the same reference numbers designate the same parts as in the compost container according to Fig. 1.

The compost container shown in Fig. 3 is designed as a self-supporting body, which is provided with a plastic and/or stainless steel inner coating and has a statically load-bearing outer skin made of polyester glass fiber and/or aluminum. The container itself is formed by a glass fiber mat, whereby due to the rotting organic waste in the rotting chamber 2, the compost container 1 is durable in the manner described above with diameters of 300 to 900 mm and a height of up to 1.5 m.

A ventilation device is provided in the area of the filling flap 4, while ventilation pipes 34 are provided on the floor area 122, laid parallel to the floor, which have holes and/or slots 35 through which the air conveyed by the foot pump 8 can escape into the rotting chamber 2 (Fig. 4).

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In addition, it is ^possible to utilize the heat that escapes vertically upwards for physical reasons, as will be explained using the example of the raised bed rapid composter shown in Fig. 5.

The longitudinal section through a raised bed rapid composter shown in Fig. 5 shows an inclined compost container 1, which is constructed similarly to the composting device shown in Fig. 1. The same reference numbers designate the same parts of the composting device explained in connection with Fig. 1. Only the holding frame 6 is constructed differently due to the inclined arrangement of the compost container 1 in stationary operation, but like the composting device according to Fig. 1, it has wheels 9 and one or more handles 10 as well as a high-pressure air foot pump 8 attached to the holding frame 6.

In contrast to the composting device according to Fig. 1, however, part of the wall of the compost container 1 has been replaced by the base plate 20 of a raised bed 13, which is also provided with a strong thermal insulation layer 90. The base plate 20 of the raised bed has a large number of openings 21 through which the heat generated during the rotting process as well as the water vapor and rotting gases generated, in particular carbon dioxide, are discharged into the raised bed or greenhouse 13.

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The raised bed or greenhouse 13 can be closed at the top by means of a translucent lid 14 and contains any plants 92 in the upper part, which are planted in topsoil 93. Beneath the topsoil there is a layer of gravel and sand as a heat reservoir, in the lowest area of the raised bed or greenhouse 13 there is a drainage device 91 through which condensed water vapor can be drained. Through the openings 21 with connecting pipes on the underside of the raised bed or greenhouse 13 it is possible to drain the water vapor produced and the resulting rotting gases, in particular carbon dioxide, into the raised bed or greenhouse 13. The plants arranged in the upper area 92 absorb a large part of the carbon dioxide and convert it into green leaf material through photosynthesis.

thereby achieving a high growth rate I

The thermally sealed rotting chamber | and the continuous rotting process make it possible to operate the composting and the raised bed ^or greenhouse 13 even in winter without additional energy.

In the composting process shown in Fig. 5 |

direction is advantageously used instead of a central J

tral pipe, a preferably multi-branched ; flat hose 30 is used, which - as explained above - is arranged with fine holes or wedge-shaped.

slots which open when the air is transferred |

pressure from the inside and at normal air pressure \

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close again so that oxygen or air can escape through these slots into the rotting chamber 2 without the openings being closed by the rotting material and water being able to penetrate into the flat hose 30*

Fig. 6 shows a cross-section through the rotting chamber and illustrates the effect of the flat hose 30/ from which oxygen or air can escape into the rotting chamber 2 in the direction of the arrow. Preferably, partition walls 8 3 are provided in the area of the flat hose 30, which divide the rotting chamber 2 into different areas.

The composting devices described above for composting liquid and organic waste are essentially made from standard parts and, due to their structural design, enable year-round operation. They are inexpensive to manufacture and can be used in any mobile manner, so that they can be used anywhere where organic waste is generated in sufficient quantities.

The centrally mounted forced ventilation by means of the ventilation device 3 in conjunction with the strong thermal insulation through the use of, for example, a polyurethane foam for the wall of the compost container 1 and through strong thermal insulation of the filling and removal opening

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a significant reduction in the rotting time is achieved and, due to the high heat development of up to 8O ⁰ C, the heat generated can be used economically. The rotting temperature in the thermophilic range guarantees homogenization of the material and also reduces the germination capacity of weed seeds. In the lower third of the rotting chamber 2, temperatures of up to 25°C are only generated, an ideal temperature for earthworms, which process the raw compost into high-quality organic compost. In addition, the high rotting temperature and the gases generated during rotting enable the operation of a greenhouse section that can be connected to the composting device, so that fruit and/or vegetables can be grown all year round, even when the composting device is used in the garden. By eliminating the need for drive units, the composting device described above enables sensible recycling and the production of high-quality organic fertilizer.

The longitudinal section through a screw rapid composting device shown in Fig. 7 shows an elongated cylindrical tube 60 serving as the housing of the composting device, in which a conveyor screw 40 extending over the entire length of the elongated cylindrical tube 60 is rotatably arranged. The elongated cylindrical tube 60 is fastened to a frame 63 which is designed in accordance with the above-mentioned

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described composting devices is suitable for transport by attaching wheels 90 to the frame 63 at the lower part of the inclined screw composting device.

At the lower end of the elongated cylindrical pipe 30, which is arranged at an angle during stationary operation, a filling nozzle 66 is provided which opens into a mixing station 50 driven by an electric motor 67. Below the mixing station 50, a paddle mechanism 51 is provided which opens into the inlet area of the conveyor screw 40. The conveyor screw 40 is driven by two synchronously running electric motors 52, 59 which are arranged at the lower and upper ends of the elongated cylindrical pipe 60.

A blower 55 presses compressed air via sliding connections 53 into the five air channels 49 in the drive shaft of the conveyor screw 40 up to individual ventilation sections 70, 71, which are arranged one behind the other in the elongated cylindrical tube 60. The connection between the blower 55 and the sliding connections 53 is made by means of a compressed air hose 56.

The elongated cylindrical tube 60 is surrounded on its outside with a thermal insulation, preferably made of polyurethane foam. To monitor the rotting process,

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temperature in the individual sections of the elongated cylindrical tube 60 are distributed over the length of the tube 60 dial thermometers 65 arranged so that the rotting process can be precisely controlled.

At the highest point of the elongated cylindrical tube 60 there is a chute 61 which can be closed by means of a gas-tight flap 62 and through which the rotted material is delivered to a pile 75 for further rotting. Also arranged in the upper region of the elongated cylindrical tube 60 is a vacuum container 58 through which the gases produced during the rotting process, essentially carbon dioxide, are sucked out at the highest point of the elongated cylindrical tube 60. The vacuum container 58 is connected to a vacuum pump 57 which has a certain j;

maintains negative pressure in the vacuum container 58. \,

In Fig. 8 are further details of the production %

snail 40 and illustrate the J

Conveying and ventilation principle of the composting device according to Fig. 7. ■

The conveyor screw 40 consists of a drive shaft 41 on which several free-standing sickle plates . 42 as well as additional sickle plates 43 are attached, which are welded to the screw plates of the conveyor screw 40« On the circumference of the drive shaft

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Air outlet holes or pipes 44 are provided distributed in the area of the screw plate, through which the compressed air or oxygen emitted by the blower 55 is blown into the rotting mass. The free-standing sickle plates 42 and the sickle plates 43 additionally welded to the screw plates ensure that there is free space within the rotting mass during the rotation of the conveyor screw 40, so that the air or oxygen or other gases blown into the individual rotting sections cause aerobic rotting.

The supply of air, oxygen or other gases to the individual ventilation sections 70, 71 along the elongated cylindrical tube 60 takes place via air ducts 45 to 49 arranged concentrically to one another and located within the drive shaft 41 of the conveyor screw 40, on which control valves are arranged in the area of the sliding contacts 53 or in the area of the ventilation sections 70, 71, via which the air supply to the individual ventilation sections can be adjusted.

The functionality of the screw composting device according to Fig. 7 and 8 will be explained in more detail below.

The organic waste to be decomposed is fed into the mixing station 50 by hand or by means of a feeding device such as a conveyor belt, an excavator or the like* via the filling nozzle 66. There

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an appropriate amount of nitrogen can be added in the form of rapid composting agents or liquid manure and the entire material can be mixed homogeneously. The paddle mechanism 51 arranged at the lowest point of the elongated pipe 60 transports the mixed material to the starting point of the conveyor screw 40 and presses it between the individual screw blades.

The conveyor screw 40 is switched on at intervals and conveys the mixed organic material at an angle of about 10* to 20° to the upper discharge point, i.e. to the pivoting discharge chute 61. The conveyor screw 40 advances by about 1.00 to 3.00 meters in 24 hours. After the specified rotting time has been reached, the mixed organic material is discharged from the elongated cylindrical pipe 60 at the highest point via the pivoting discharge chute 61 and reaches the pile 75 for further rotting.

To achieve the high rotting temperatures of approx. 60°C to 80°C, it is necessary to supply the rotting bacteria present in the organic mixture with sufficient oxygen. This is done via the blower 55, which blows compressed air via the compressed air hose 56 and the sliding contacts 53 into the air ducts or air pipes 45, 49 arranged in the drive shaft 41, via which the compressed air or oxygen is conveyed to the individual ventilation sections 70, 71. The individual ventilation sections make it possible to

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In conjunction with the control valves, concentrated air, oxygen or other gases can be supplied to the individual rotting sections and the rotting process can be precisely controlled.

The same effect as with the free-standing additional screw plates attached to the screw plates can be achieved by screwing bent pipe ends onto the drive shaft 41 of the conveyor screw 40, from which air from the individual ventilation sections 70, 71 of the elongated cylindrical pipe 60 is pressed into the rotting mass.

At the same time as fresh air, oxygen or other gases are blown in, the gases produced during the rotting process, mainly carbon dioxide, are sucked out at the highest points of the elongated cylindrical tube 60 by the vacuum container 58 in conjunction with the vacuum pump 57. These heated gases and the carbon dioxide they contain can be used to heat a greenhouse, a nursery or the like.

The screw composting device described above can be modified and supplemented in many different ways. Since the air outlet holes 44, which are arranged around the circumference and along the length of the drive shaft 41, are extremely sensitive to blockages caused by the rotting mass, the drive shaft 41 can be provided with small holes* which are filled with a microscopic

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fine slit rubber. This will make it^
is sufficient/ that only when air is supplied from the inside of the drive shaft 41 or from the air ducts 45 to 49
with appropriate pressure against the rubber slots, these open and then close again/ if rotting mass from outside
* The central ventilation system, divided into many ventilation sections, guarantees
that an aerobic hot fermentation in a very short time

takes place. This hot fermentation can be carried out using |

which extends over the length of the elongated cylindrical 1

dric tube 60 distributed pointer f

thermometer monitors and thus the rotting process |

made visible* |

Due to the special design of the compost container |

ters as an elongated cylindrical tube it is £

easily possible to seal the pipe from the outside with preferably f

Polyurethane rigid foam for seamless insulation.

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Aluminium coating should be provided so that |

cold radiation is prevented even in winter. |

This additional insulation of the compost bin

ters ensures that the required |

high rotting temperatures can be achieved and also |

trouble-free winter operation is possible. I

t The screw composting system described above

device is particularly suitable for mobile use for pre-composting, whereby it is possible to

can be transported to collection points where -

Larger quantities of garden and kitchen waste are generated,

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which are not disposed of using the so-called surface composting. The resulting organic waste can be processed into high-quality organic fertilizer at various points in a community using the device described above and can be reused as recycling material by private individuals and garden centers.

Claims (5)

Device for composting organic waste Claims 1. Device for composting organic waste with a compost container forming a rotting chamber with a bin filling opening arranged at one end for filling in the organic waste and a removal opening provided at the opposite end for removing the compost and a ventilation device arranged in the rotting chamber, characterized in that the compost container (1) is provided with a holding frame (6) for mobile transport and vertical or obliquely inclined positioning of the compost container (1) and that the ventilation device (3) extends essentially over the entire length of the rotting chamber (2) and/or the floor (122) of the compost container (1) and with DN/em Märtinistraße 24 Telephone >, · <·; _t > · ,TeJejop.iprer · &diams;; · · -Telex D-28ÖÖBremen! Ö42i-3iJ30.37 &iacgr;:<&EEgr;21-3168 M "'2440 Datex P 44421040311 a compressed air pump or a blower (8). 2. Device according to claim 1, characterized in that the filling opening (11) and the removal opening (12) can be closed with a filling flap (4) and a removal flap (5) respectively and that the walls of the compost container (1), the filling flap (4) and the removal flap (5) are provided with a heat-insulating layer (7). 3. Device according to claim 1 or 2, characterized in that the holding frame (6) for manual transport of the compost container (1) is provided with wheels (9) in the area of the removal opening (12) and one or more handles (10) in the area of the filling opening (11). 4. Device according to one of the preceding claims, characterized in that the compost container (1) is designed as an elongated, cylindrical tube or as an elongated drawer or in the manner of a garbage container and is arranged vertically or inclined in stationary operation, such that the filling opening (11) is arranged at the highest point of the compost container (1) and the removal opening (12) is arranged at the lowest point of the compost container (1). ;| 5. Device according to one of the preceding sayings t »&igr;&igr; I t I I * ' i J ! characterized in that the ventilation device (3) consists of a plastic tube with longitudinal slots (31) provided in its wall. β. Device according to one of the preceding claims i to 4, characterized in that the ventilation device (3) consists of a plastic tube with holes provided in its wall and an elastic covering provided with holes and/or slots. 7. Device according to one of the preceding claims 1 to 4, characterized in that the ventilation device (3) consists of one or more flat hoses (30) with slots (31). 8. Device according to one of the preceding claims 1 to 4, characterized in that the ventilation device (3) consists of a porous plastic or stone pipe. 9. Device according to one of the preceding claims 4 to 7, characterized in that the bores and/or slots (31) are provided continuously over the entire length of the ventilation device (3). 10. Device according to one of the preceding sayings, I ; t &iacgr; »t1 * &igr; characterized in that the compost container (1) is designed as a self-supporting body with a plastic and/or stainless steel inner coating, a statically load-bearing outer skin made of polyester glass fiber and/or aluminum and a glass fiber mat as compost container (1), whereby the ventilation device (34) consists of pipes (34) with slots and/or holes (35) laid on the bottom (122) of the compost container (1). 11. Device according to one of the preceding claims 1 to 9, characterized in that a part of the wall of the compost container (1) is expanded to form a box-shaped raised bed (13), the bottom (20) of the raised bed (13) being arranged at the location of the container wall and being provided with openings (21). 12. Device according to one of the preceding claims, characterized in that the filling opening (11) is provided with a device (15) for shredding coarse or bulky organic waste, which is preferably arranged in an insert of the filling flap (4). 13. Device according to one of the preceding claims, characterized in that the compressed air pump or the blower (8) can be operated manually. 14. Device according to claim 13, II .111 ti i · ·* ItI I < . , ■ ■ . , Il · IiIIIi I . ,ItI III II · characterized in that the compressed air pump (8) is designed as a foot pump. 15. Device according to claim 14^ characterized in that the foot pump (8) is Kalterahntsn (6) of the KonrpOatbeilalcers (i) fasten is. 16 * Device according to claim 1, characterized in that the compost container (1) consists of an elongated, cylindrical tube (60) in which a conveyor screw (40) is rotatably arranged, in the drive shaft (41) of which at least one air channel (45) is provided and is connected on the one hand to the compressed air pump or the blower (8) and on the other hand to several air outlet openings (44) distributed on the drive shaft (41). 17. Device according to claim 16, characterized in that several concentric air channels (45 to 49) are provided which lead to ventilation sections (70, 71) arranged one behind the other in the cylindrical tube (60). 18. Device according to claim 16 or 17, characterized in that several further tubes (45 to 49) designed as air channels are arranged in the cylindrical tube (60) and are firmly connected to the cylindrical support tube (60) and closed at the air transfer point, with a grinding element (53, 54) for each tube (45 to 49) . ,, «I lilt .· · 4 «· ata a &igr;&igr;&igr; · &igr; · * a · &igr; t &igr;&igr;&igr; · · · is provided, via which the relevant ventilation section (70, 71) can be supplied with fresh air, oxygen or other gases. 19. Device according to one of the preceding claims 16 to IS, characterized in that a plurality of distributed air outlet openings (44) are provided in the drive shaft (41), which are covered with a microscopically fine slotted rubber. i 20. Device according to one of the preceding claims 16 to 19, characterized in that on the drive shaft (41) of the conveyor screw (40) free-standing sickle plates (42) and additional screw plates (43) are attached. 21. Device according to claim 16, &igr; characterized in that on the drive shaft (41) of the conveyor screw (40) bent pipe ends are screwed in, from which air from the individual Ventilation sections (70, 71) of the drive shaft (41) are released to the rotting mass. 22. Device according to one of the preceding claims 16 to 21, characterized in that openings (65) are provided in the upper region of the elongated cylindrical tube (60) which are connected to a vacuum container (58) with a vacuum pump (57).