DE10016050A1 - Composting container inner chamber sub-divided into two zones over perforated tilting base panels - Google Patents

Abstract

A composting assembly has an angled rocking base and e.g. a domed or inverted funnel housing (1) with an organic refuse inlet (10) to a composting chamber (20). The composting chamber has especially two adjacent zones (20a , 20b). The base panels (A, B) have water drainage holes. The side panels and hatch have air ventilation holes. The housing may be tilted from side to side about an axis (8) at chosen intervals, inverting the container contents. The base panels (A, B) are hinged flaps.

Description

The invention relates to a composter for composting organic house and garden waste according to the preamble of claim 1 and an operating method for such a gene composter according to the preamble of claim 29.

The disposal of the increasing amount of waste puts a strain on limited landfill spaces, Ener greed resources and the environment. Therefore, the rotting portion of the garbage is tried coming separately to collect and compost by separate collection. Let it go organic waste is recycled and stored in humus, d. H. valuable food for plants umwan spindles.

Since the compostable portion of the total household waste is approx. 40% through separate composting great potential available on the one hand, the total reduce waste and, on the other hand, organic waste through composting again attributed to the natural cycle. In this natural recycling process, Mi Croorganisms and small animals (worms, bacteria, fungi) involved. Prerequisite for one favorable course of aerobic rotting are a balanced air-moisture ratio and a sufficient temperature. If there is a lack of air and therefore oxygen, the aerobic is replaced Rotten anaerobic decomposition, and such a putrefaction leaves unpleasant smells che arise.

To carry out aerobic rotting on unpaved ground, especially in the garden area, are in addition to the simple filling in the form of a compost heap more or min the functional composting systems known.

In the case of open composting systems, which generally consist of just one compost Rende material surrounding supporting fencing, such as one Slatted composter, the material to be composted is strongly exposed to the weather. except a large amount of compost is required for a heat-retaining self-insulation occurs. Large amounts of compost in a relatively high stratification displace air spaces and act there with a balanced air-moisture ratio. As a result of this Composting material is labor-intensive loosened up by digging and aerated.  

Closed composting systems, e.g. B. thermal composter, where the complicated shifting of the composting material is to be avoided, since such systems me have a relatively small compost mass. To ensure adequate warming insulation To ensure these systems consist in many cases of a closed with a lid its container. The material to be composted is completely sealed off partly insufficiently ventilated due to insufficient ventilation openings. Wetness that due to a too large proportion of damp material, it can hardly be dissipated the. Since the excess water displaces the air spaces, there is also a risk here anaerobic decomposition. One tries to prevent that dry and damp Material is only fed into the container in a ratio that is favorable for the aerobic compost. Strict control of the carbon-nitrogen ratio (dry material / wet material) required to transition to anaerobic decomposition and hence the To prevent rotting from occurring. To stabilize the aerobic rotting are often said to Additional additives that promote degradation, such as chemical accelerators or decomposing ores ganisms, artificially added.

It is also disadvantageous that many previously known systems are completely dismantled or converted and have to be emptied in order to access the already rotten material or to to separate it from the immature, not yet mined material.

A composter on which the preamble of the independent claims is based according to DE 43 38 634 C1, which has to be classified between the open and closed systems a tiltable housing in which three sieve trays form two receiving chambers. Through a Tilting the housing is also intended on the one hand to remove composted, mature material be exposed and, on the other hand, fresh material still to be composted are loosened, while also the mature and the immature material parts from each other be separated. The size and the separating plate designed as a sieve plate between the opening chambers of this two-chamber tipping system, however, increase acquisition costs, Transport weight and volume. This additional effort is justified if There is a need for a system capacity of around 500 liters, since it works well and manageability. If you need a system capacity up to 300 liters, this is However, the system is unsuitable because it is fully populated for optimal functionality have to be.

Regarding the previously known composting systems, it can finally be stated that the achievement a balanced oxygen supply to the compost mass and to ensure the aerobic rotting the compost material is either labor-intensive shifted or strictly controlled  or that, as in the last described case, the purchase of the compo bull system is relatively expensive.

The invention is based on the task, a composter described above NEN way to develop and create an associated operating procedure that without Agile redeployment and control measures the conditions for an aerobic Rotting is easy to keep and easy to handle when loading and unloading guaranteed. In addition, if necessary, in contrast to the two-way described mern tilting system the need for a smaller capacity as well as for less purchase and transportation costs are covered.

This object is achieved by a composter with the features of claim 1 and an operating method with the features of claim 29 solved.

It is intended to transfer the composter from one end position to the other, the material in the first area of the receiving chamber already being removed is fully composted, while that in the second area of the receiving chamber Material is still in a relatively immature condition. The finished composted material will then removed from the first area of the receiving chamber and at the same time that remains still immature material in the second area of the receiving chamber in the composter. By the transfer tion movement by setting the housing down on the other shelf will do so last filled area of the receiving chamber, only partially rotted material loosened up so that there is better ventilation. Through drainage floors is a constant Air circulation guaranteed by the material. The continued air circulation also leads to the Moisture present in the receiving chamber is removed, thereby preventing rotting can be. The material to be composted is surrounded by a housing, which ne negative effects of weather influences on the decomposition process largely closes and at the same time forms a certain thermal insulation. The Kom according to the invention poster combines the advantages of the closed and the open composting system.

In order to achieve good access to the composted material, the housing forms according to claim 3 each by the transfer from one end position to the other End position released storage area in connection with one of the drainage floors the drainage opening can be closed. Because the shelves of the case Sizing should be relatively large by loosening the respective Drainage floor from the housing a relatively large removal opening can be achieved. This ent stands by the relative movement between the one transferred from one to the other end position  Housing, compared to the remaining in its starting position near the floor, from Housing detached drainage floor.

With an arrangement of the pivot axes according to claim 4 results in the longitudinal section of the Ge housing a funnel-shaped receiving chamber. Because in this embodiment during the Transfer movement with all surfaces on which the material to be composted rests are moved, there is good ventilation while avoiding putrefaction.

According to claim 5, the housing may have a receiving opening in the middle, which with a housing piece is closable, which is adapted to the contour of the housing and before protects against the intrusion of birds.

According to the above requirements, the housing itself can be different Be designed in such a way, plastic to achieve cheaper manufacturing options parts are to be considered. A appears advantageous in a first embodiment Shaping according to claim 7, in which the housing is placed in each case through the tilt axis Cross-sectional areas essentially the contour of a half divided along its minor axis Ellipse, preferably a 30 ° ellipse (A 30 ° ellipse is created by circular projection under an angle of 30 °. The major axis of the ellipse is twice as long as the minor axis.) having. Regardless of the cross-sectional shape of the housing, it may be appropriate Drainage floors, except for a relatively narrow movement gap, essentially the inner contour to adapt the housing. This can cause material to fall through between the Ge housing and the drainage floors can be prevented. Through several fixing options Drainage floors on the housing can optionally be an advantageously adjustable smaller train the receiving chamber.

In an embodiment according to claim 11, the composter can from an end position in a Zwi be transferred, the one located in the first area of the receiving chamber Material is already composted ready for removal, while that in the second area of the Receiving chamber material is still in a relatively immature state. The finished composted material is then removed from the first area of the receiving chamber At the same time, the still immature material remains in the second area of the recording chamber in the composter. It is also provided that the composter from its intermediate layer in the to transfer another end position, so that the previously emptied first region of the receiving chamber can be refilled. The desired loosening and ventilation of the material also occurs here  on. Since the intermediate floor and drainage floors form wall parts of the receiving chamber a constant air circulation through the material is guaranteed.

For this system, a funnel shape appears advantageous in the side view, the through which two converging shelves formed by the tip arranged between them third shelf is blunted and in the two end positions between the third Storage space and the sub-floor, one angle segment remains free, which is smaller or equal 90 ° and greater than or equal to 45 °.

In order to achieve good access to the composted material, the housing forms according to claim 12 in each case by the in the transfer from the one end position in the Intermediate storage space in connection with one of the drainage floors Removable opening that can be closed by the drainage floor. This arises from the relative movement between the housing transferred from the one end position to the intermediate layer, compared to the remaining in its starting position near the ground, from the housing ge loosened drainage floor.

A particularly simple transfer movement of the housing into its end positions and possibly the intermediate layer can be there in both embodiments according to claims 18 or 19 can be achieved that the housing is tiltable. The housing can do this advantageously be designed like a skid in the region of the pivot axes. The center of gravity of the loaded housing and the built-in parts is advantageously chosen so that the tilting from one storage area to the other without considerable effort. Most of all the focus of the compost mass to be moved when the housing is tilted through the Overall geometry of the housing in connection with the drainage floors and if necessary the Zwi Chenboden chosen so cheap that there is already a slight shift in focus it is enough to tip the loaded composter independently by its weight.

The drainage floors can expediently have recesses and, for example, of Be plastic. Other structural designs, for example perforated sheets or wire mesh with a frame are also possible. The size of the recesses should be be coordinated so that on the one hand the material to be composted is not affected by the Soils can fall through, and that, on the other hand, small animals, such as worms, prevent rotting Promote process, can get into the area of the reception chamber in which the fresh waste is present. By coordinating the recesses in this way unwanted intrusion of larger animals such as rats can also be prevented.  

To operate the composter can be advantageous according to an operating method according to claim 29 be in which the loading of the receiving chamber of the housing takes place cyclically, that at the beginning of the first composting cycle, first the first and then the second Area of the receiving chamber is filled while the housing on its first Abstellflä che is discontinued. After a tilting movement of the housing and settling on the second Ab Space after the composting time of the material in the first area of the recording chamber the first area of the receiving chamber should then be released for removal, then around the first area of the receiving chamber with the one fixed to the housing Seal and fill up drainage floor.

After a further tilting movement of the housing and settling on the first shelf after the composting time of the material in the second area of the receiving chamber and after loosening the corresponding drainage floor, the second area of the receiving chamber is released for removal. Furthermore, after the second region of the receiving chamber has been emptied, the corresponding drainage base for refilling the second region of the receiving chamber is fixed to the housing in order to then alternately fill and empty the two regions of the receiving chamber as often as desired. With this loading process of the composter, several advantages can be achieved:
Since, except for the first composting cycle, the fresh material is always poured into the upper area of the receiving chamber, which is assigned to the floor-free storage space, the air circulation necessary in particular for this relatively moist material is ensured. Excess rainwater penetrating into the receiving chamber can flow off through the drainage floors. This helps to achieve a balanced air-moisture ratio. Advantages of use in this operating method also result from the fact that the material which has already been composted is in the area of the receiving chamber which is assigned to the current storage area of the composter before the housing is tilted. When the composter is transferred from one end position to the other, the already composted material does not have to be moved, but can remain deposited on the drainage base on the bottom, which has been released from its locking on the housing. The movement of the housing relative to the stationary drainage soil carrying the composted material forms a generous removal opening at the same time as the transfer movement, so that the finished compost can be easily removed with appropriate equipment.

For the operation of the composter according to claims 11 to 28, the operating method supplementary according to claim cyclically so that at the beginning of the first composting cycle  first the first and then the second area of the receiving chamber filled while the case is set down on its first shelf. After a kippbe movement of the housing and settling on the third shelf after the compost time of the material in the first area of the receiving chamber and after loosening the ent speaking drainage floor should then be the first area of the receiving chamber for removal be released in order to subsequently close the housing with the drainage base, tilt to the second end position and fill the first area of the receiving chamber.

After a further tilting movement of the housing and settling on the third shelf after the composting time of the material in the second area of the receiving chamber and after loosening the corresponding drainage floor, the second area of the receiving chamber is released for removal. Furthermore, after emptying the second area of the receiving chamber, the corresponding drainage base is fixed to the housing and tilted into the first end position, in order to then alternately fill and empty the two areas of the receiving chamber as often as desired. With this loading procedure for the Kom poster, several advantages can be achieved:
Although the composter can be designed in different sizes depending on the area of application, it appears to be particularly useful with two storage areas, the height and width of which are each about 0.9 μm, with a capacity of about 500 l. Compost material without thermal insulation requires a volume of approx. 750 l to isolate itself. With the help of the special housing shape proposed here, however, 500 l are sufficient. With a smaller volume, this container would have to be closed and could then u. May no longer offer the desired ventilation option. In the case of containers larger than 500 l, the greater weight of the compost mass can have a negative effect on the oxygen supply to the feed. Such a composter ensures good rotting function with little effort and enables high compost quality. Depending on the weather conditions and the material to be used, the duration of the red is approx. 5 months in summer and 7 months in winter, while the removal intervals are on average 2.5 to 3.5 months due to the mutual availability.

In the case of a composter with a mezzanine, an education appears at the height and Width is about 0.6 m each, particularly useful with a content intake of approx. 2251 moderate. With the help of the special housing shape proposed here, this amount is already out sufficient because the container is closed except for the ventilation openings in its drainage floors  is executed. He can due to the ventilation openings, the relief Geometry and the movement but still offer the desired ventilation option.  

The invention is based on the embodiment shown schematically in the figures explained in more detail; show it:

Fig. 1 is a front view of a composter moderate invention in a first execution example with two shelves,

Fig. 2 shows a section through the composter of FIG. 1 (but with an example of a housing piece closing the receiving opening) along the line II-II in Fig. 1st

Fig. 3 is a plan view of the composter in Fig. 1,

Fig. 4 is a principle side view of the Kam poster in its first end position.

Fig. 5 is a schematic side view of the composter in its second end position.

Fig. 6 is a front or rear view of a composter according to the invention in a further embodiment with three shelves

Fig. 7 is a sectional view through the composter of FIG. 6 taken along the line II-II in Fig. 6,

Fig. 8 is a plan view of the Kam posters according to Fig. 6,

Fig. 9 is a schematic side view of the composter in its first end position,

Fig. 10 is a schematic side view of the composter in its second end position,

Fig. 11 is a principle side view of the composter in its intermediate position.

In FIGS. 1-5, in a first embodiment of a composter is shown, which has a preferably one-piece housing 1 made of durable plastic, are preferably arranged in the two pivotable drainage shelves 2, 3 in the walls of the housing 1. The two drainage floors 2 , 3 each consist of a semi-elliptical plate which is provided with ventilation openings. Tilting runners 6 and bearing formations 5 are located on both sides of the housing. In the bearing formations 5 , the drainage floors 2 , 3 are each mounted in bearings 7 , 8 with parallel pivot axes. Spacer elements 10 , 11 are provided in the apex region of the drainage floors 2 , 3 .

The hood-shaped housing 1 of the composter shows in its cross-sectional areas essentially a habelliptical contour through the tilting axis, to which the contours of the drainage bases 2 , 3 are adapted with a spacing gap. For the optional fixing of one of the two Draina floors 2 , 3 on the housing 1 , an implementable, plug-like locking element 14 is seen before, which optionally engages with holding pins 15 in housing recesses 16 , 17 . The receiving opening 18 can expediently be closed with a housing piece shown only in FIG. 2, which is adapted to the contour of the housing. The both sides of the Ge housing arranged skids 6 can, for. B. be connected by an anti-tipper 19 which wel should prevent sinking into the ground 12 a.

Referring to FIG. 2, the two drainage shelves 2, 3 in conjunction with the walls of the Ge häuses 1 in longitudinal section a funnel-shaped receiving chamber 20 with two regions 20 a, 20 b form. The side walls of the receiving chamber 20 formed by the housing 1 are provided with ventilation recesses 22 .

To remove the composted material, for example from the first area 20 a of the receiving chamber 20 , in which the housing 1 rests on the substrate 12 a with its first standing surface A in the end position shown in FIG. 4 with the locking element 14 released , it is necessary that Implement housing 1 on the second footprint B ( Fig. 5). The housing 1 , together with the Draina floor 3 fixed by the locking element 14 on the housing 1, is transferred from one end position to the other, in which the housing 1 stands up with the two base surface B. The relative movement between the housing 1 and the drainage floor 2 then releases a relatively large removal opening in the area of the first stand area A. The same applies if the material to be removed is in the second loading area 20 b of the receiving chamber 20 and the housing 1 is tilted from its second base surface B to support the first base surface A in the opposite direction onto the substrate 12 a ( FIG. 5) ,

The process sequence begins, for example, in a position of the composter, as shown in FIG. 4, by filling the first area 20 a of the receiving chamber 20 , the drainage base 2 of which faces the first standing area A standing on the ground 12 a. If the introduced material a of the receiving chamber 20 is no more room in the first region 20, second region 20 of the receiving chamber 20 b refilled.

After the rotting time for the first area 20 a of the receiving chamber 20 , the composter is tilted over the tilting skids 6 from its one end position with the support of the first standing surface A into its other end position. Now the composter with its second footprint B rests on the substrate 12 a ( FIG. 5). As already described above, the composted material is removed from the first region 20 a of the receiving chamber 20 through the removal opening that arises between the first standing surface A and the drainage floor 2 .

After removal, the drainage floor 2 can be fixed to the housing 1 again by inserting the locking element 14 into the recesses 17 . Now the first area 20 a of the receiving chamber 20 can be refilled. If the fill level of the first area 20 a of the receiving chamber 20 is reached, or the rotting time of the material in the second area 20 b of the receiving chamber 20 has elapsed, the com poster is tilted onto the first stand area A. The material can be removed in this position of the grain poster from the second area 20 b that take place through the removal opening formed between the drainage floor 3 shown in the near-floor position and the second standing area B of the housing ( FIG. 4).

After fixing the drainage floor 3 on the housing 1 by inserting the locking element 14 into the recesses 16 of the housing 1 , further loading cycles with mutual filling and emptying of the two areas 20 a, 20 b of the receiving chamber 20 can be carried out.

By supporting the other drainage floor 2 , 3 with the spacer 10 and 11 on the substrate 12 a but also between these drainage floors and the underground the amount of air for rotting reaches the corresponding area of the receiving chamber, the footprint of which is just up the underground is 12 a. Since au that the composting process supporting small animals ßerdem fresh material Favor gene is ensured by forming the drainage floors with recesses that they migrate from the substrate 12 a respectively in the region of the receiving chamber that contains the fresh material.

In the first embodiment of the composter shown here, the filling volume of the receiving chamber 20 is approximately 500 liters.

In the other Figs. 6-11 a composter is shown in a further embodiment, which is a composite of three parts housing 1 has impact-resistant plastic, in which a fixed intermediate base 255 and two pivoting drainage shelves 2, 3 attached are arranged. The two drainage floors 2 . 3 each consist of a square plate, which is provided with ventilation openings. Tilting runners 6 and bearing recesses 5 are located on both sides of the housing. In the storage recesses 5 , the drainage floors 2 , 3 are each mounted in bearings 7 , 8 with parallel pivot axes. In the apex area of the drainage floors 2 , 3 , locking formations 30 , 31 are provided.

The housing 1 of the composter shows in its cross-sectional areas by the pivot axes essentially a trapezoidal contour which is adapted to the contours of the drainage floors 2 , 3 with gap from. To fix the two drainage floors 2 , 3 to the housing, two plug-like locking elements 14 a, 14 b are provided, which engage in the housing recesses 16 , 17 with retaining pins 15 a, 15 b.

The tilting skids 6 arranged on both sides of the housing are expediently connected by an intermediate floor 25 which is provided with ventilation openings. It forms a third space C from the housing 1st According to Fig. 7 here as well, the two drainage shelves 2, 3 in conjunction with the intermediate base 25 and the housing 1 in longitudinal section a trichterför-shaped receiving chamber 20 with two mirror-symmetrical areas 20 a, b 20 form.

To remove the composted material, for example from the first area 20 a of the receiving chamber 20 , in which the housing 1 with its first storage surface A is in the end position shown in FIG. 9 with the locking element 14 a locked on the base 12 a, it is necessary to convert the housing 1 to the third shelf C ( Fig. 11). The locking element 14 a is unlocked and the housing 1 is transferred together with the drainage base 3 fixed by the locking element 14 b to the housing 1 from the first end position into the intermediate layer in which the housing 1 stands up with the third storage area C. The relative movement between the housing 1 and the drainage floor 2 then releases a relatively large removal opening in the region of the first storage area A.

To fill the previously emptied, for example first area 20 a of the receiving chamber 20 , it is necessary to move the housing onto the other storage surface B. For this purpose, the housing is transferred from the intermediate position into the second end position, in which the housing 1 stands up with the second storage surface B. The relative movement between the housing 1 and the drainage floor 2 then releases a relatively large filling opening in the area of the first storage area A. After filling, the first area 20 a of the receiving chamber is closed with the drainage floor 2 fixed to the housing 1 . The same applies if the material to be removed is located in the second area 20 b of the receiving chamber 20 and the housing 1 is tilted from its second storage surface B to support the third storage surface C in the opposite direction and then from its third storage surface C to the support again the first shelf A to be tilted back in the opposite direction on the surface 12 a.

The process sequence begins, for example, in a position of the composter, as shown in FIG. 9, by filling the first area 20 a of the receiving chamber 20 , the drainage base 2 of which faces the first storage area A standing on the ground 12 a. Nominal the introduced material is no place a receiving chamber 20 is greater in the first region 20, second region 20 of the receiving chamber 20 b refilled.

After the rotting time for the first area 20 a of the receiving chamber 20 , the composter is tilted over the tilting skids 6 from its first end position with the support of the first storage surface A into its third end position. Now the composter lies with its third shelf C on the ground 12 a ( Fig. 11). As already described above, the composted material is removed from the first region 20 a of the receiving chamber 20 through the removal opening that arises between the first storage surface A and the drainage floor 2 . After removal, the drainage floor 2 can be fixed to the housing 1 again by inserting the locking element 14 a into the recesses 16 . For renewed loading of the emptied first area 20 a of the receiving chamber 20 , the housing 1 is tilted from the intermediate layer C into the second end position B ( FIG. 10).

If the fill level of the first area 20 a of the receiving chamber 20 is reached, or the rotting time of the material in the second area 20 b of the receiving chamber 20 has elapsed, the composter tilts onto the third storage area C. The material can be removed in this position of the composter from the second area 20 b through the removal opening he follow, which forms between the drainage floor 3 shown in the near-ground position and the second shelf B of the housing ( FIG. 11).

After fixing the drainage floor 3 on the housing 1 by inserting the locking element 14 b into the recesses 17 of the housing 1 , or after unlocking, further loading cycles can be carried out with mutual filling and emptying of the two areas 20 a, 20 b of the receiving chamber 20 ,

Through the drainage floors 2 , 3 with the ventilation openings but also between these drainage floors and the subsurface the amount of air sufficient for rotting reaches the corresponding area of the receiving chamber, the storage surface of which is currently on the subsurface 12 a. In addition, since the small animals that support the composting process prefer fresh material, it is ensured by designing the drainage floors with recesses that they wan from the substrate 12 a to the area of the receiving chamber, which contains the fresh material.

In the second embodiment of the composter shown here, the filling volume of the receiving chamber 20 is approximately 225 liters.

The air space remaining after filling the upper area of the receiving chamber In both cases, the fresh material enables a particularly for this moist material necessary good air circulation.

Claims (31)

1. composter for composting organic house and garden waste, in which a Ge housing ( 1 ) for receiving the material to be composted during the Kompostievor gear is movable, the housing ( 1 ) at least one opening ( 18 , 18 a, 18 b ) for loading the composter and on at least two layers, a first and a second storage surface (A, B, C) are formed for depositing the housing and wherein in the housing ( 1 ) a egg chamber ( 20 ) is formed, characterized in that in the Housing ( 1 ) a single receiving chamber ( 20 ) with two alternately successively feedable areas ( 20 a, 20 b) is provided. 2. Composter according to claim 1, characterized in that the storage surfaces (AB) form end positions during the transfer movement of the housing ( 1 ). 3. Composter according to one of claims 1 or 2, characterized in that the Ge housing ( 1 ) in each case by the released upon transfer into one of the two end positions from the storage area (A, B) in conjunction with at least one of the storage areas (A, B) assigned, preferably pivotable drainage floor ( 2 , 3 ) forms a closable removal opening. 4. Composter according to claim 3, characterized in that the pivot axis ( 7 ) of the drainage floor ( 3 ) of the second shelf (B) in the region of the pivot axis ( 8 ) of the drainage floor ( 2 ) of the first shelf (A) is arranged so that A funnel-shaped receiving chamber ( 20 ) can be formed in the longitudinal section of the housing. 5. Composter according to one of claims 1 to 4, characterized in that the opening ( 18 ) with a housing piece ( 4 ) can be closed, which is adapted at least at its edges to the contour of the housing ( 1 ). 6. Composter according to claim 5, characterized in that the two in the area of the shelf (A, B) of the housing ( 1 ) arranged fixable drainage floors ( 2 , 3 ) with substantially parallel pivot axes ( 7 , 8 ) in the region of a tilting arrangement are not. 7. Composter according to one of claims 1 to 6, characterized in that the hous se ( 1 ) has a semi-elliptical contour in cross-sectional areas through an imaginary intersection of the levels of the drainage panels and that the drainage bases ( 2 , 3 ) in their cross-sectional areas in Are essentially adapted to the contour of the housing ( 1 ). 8. Composter according to one of claims 1 to 7, characterized in that the hous se ( 1 ) and the drainage floors ( 2 , 3 ) are each an integral plastic part. 9. Composter according to one of claims 1 to 8, characterized in that the height and width of the housing ( 1 ) is each about 0.9 m. 10. Composter according to claim 14, characterized in that the housing is between NEN both beach areas A and B in longitudinal section form an angle that is smaller or is equal to 120 °. 11. Composter according to claim 1 or 2, characterized in that between the two end positions in an intermediate layer of a third shelf (C) is formed by an intermediate floor ( 25 ). 12. Composter according to claim 11, characterized in that the housing ( 1 ) in each case by the in the transfer into the intermediate layer (C) released storage area (A, B) in connection with one of the drainage floors ( 2 , 3 ) one through the drainage floor ( 2 , 3 ) forms a closable removal opening. 13. Composter according to claim 11 or 12, characterized in that the substantially parallel pivot axes ( 7 , 8 ) of the drainage floors ( 2 , 3 ) in the area of the third storage surface (C) are arranged so that the two in the area of the first and the second storage surface (A, B) of the housing ( 1 ) arranged fixable drainage floors ( 2 , 3 ) with the intermediate floor ( 25 ) arranged in the region of the third storage surface (C) of the housing in longitudinal section enclose an obtuse acute angle. 14. Composter according to one of claims 11 to 13, characterized in that the Ge housing ( 1 ) in its cross-sectional areas through an imaginary intersection of the levels of the drainage floors has the contour of a trapezoid and that the drainage floors ( 2 , 3 ) in their ren cross-sectional areas are essentially adapted to the contour of the housing ( 1 ). 15. Composter according to one of claims 11 to 14, characterized in that the Ge housing ( 1 ) with the two drainage floors ( 2 , 3 ) and the intermediate floor ( 25 ) is composed essentially of 6 plastic parts. 16. Composter according to any one of claims 11 to 15, characterized in that the height and the width of the intermediate housing on the third shelf (C) separated Ge housing ( 1 ) is each about 0.6 m. 17. Composter according to claim 10, characterized in that the housing is between ner first and its second shelf (A, B) enclose an angle in longitudinal section, which is less than or equal to 90 °. 18. Composter according to one of the preceding claims, characterized in that the housing ( 1 ) is designed to be tiltable for transfer to its storage surfaces. 19. Composter according to one of the preceding claims, characterized in that the housing ( 1 ) is designed to be tiltable in two end positions and optionally in an intermediate position. 20. Composter according to one of the preceding claims, characterized in that tilting skids ( 6 ) are formed for tilting on the housing ( 1 ). 21. Composter according to claim 20, characterized in that in the region of the tilting runners ( 6 ) bearing recesses ( 5 ) for the pivot axes ( 7 , 8 ) of the drainage floors ( 2 , 3 ) are formed. 22. Composter according to claim 20 or 21, insofar as it is drawn back to one of claims 11 to 19, characterized in that the intermediate floor ( 25 ) is arranged between the tilting runners ( 6 ). 23. Composter according to one of the preceding claims, characterized in that the housing ( 1 ), the drainage floors ( 2 , 3 ) and possibly the intermediate floor ( 25 ) consist of heat-insulating material. 24. Composter according to one of the preceding claims, characterized in that on the drainage floors ( 2 , 3 ) spacer elements ( 10 , 11 ) are provided which each keep the drainage floor ( 2 , 3 ) assigned to the storage surface free of soil. 25. Composter according to one of the preceding claims, characterized in that the drainage floors ( 2 , 3 ) have ventilation openings. 26. Composter according to one of the preceding claims, characterized in that the housing ( 1 ) in its side walls at least in the region of the pivot axes ( 7 , 8 ) has ventilation recesses ( 22 ). 27. Composter according to one of the preceding claims, characterized in that locking recesses ( 10 , 11 ) are provided on the drainage floors ( 2 , 3 ). 28. Composter according to one of the preceding claims, characterized in that at least one locking element ( 14 ) is provided with which the drainage floors ( 2 , 3 ) in the region of the two storage surfaces (A, B) on the housing ( 1 ) can be fixed. 29. Operating method for a composter according to one of the preceding claims, there characterized in that the loading of the receiving chamber takes place such that at Beginning of the first composting cycle of the first and second areas of the intake chamber can be filled one after the other while the housing on its first shelf che (A) is deposited and that after a tilting movement of the housing and settling on the second shelf (B) after the composting time of the material in the first Area of the receiving chamber the first area of the receiving chamber is free for removal is given that the first region of the receiving chamber with that fixed to the housing Drainage floor is closed and filled, and that after a tilting movement of the Housing and settling on the first shelf (A) after composting time of the material in the second area of the receiving chamber and after loosening the ent speaking drainage floor the second area of the receiving chamber for removal is released, and that further after clearing the second area of the receptacle chamber the corresponding drainage floor for re-loading the second load is richly fixed to the housing on the housing, then the two areas of the Fill and empty the receiving chamber alternately as often as desired. 30. Operating method according to claim 29, characterized in that at the beginning of each Composting cycle the housing is set down on a shelf, each of which  lower area of the receiving chamber is filled after the tilting of the housing and only the upper area of the receiving chamber is loaded. 31. Operating method for a composter according to one of claims 11 to 30, characterized ge indicates that the composter in its two end positions alternately on the he most and second shelf (A, B) is filled, alternately on the ge opposite shelf (B, A) and that it is used to empty the area composted material in an intermediate layer on the between the shelves (A, B) formed third shelf (C) is transferable.