DE19653116A1 - Composting container base - Google Patents

Abstract

A composting container has an air inlet in the base surrendering the air to the compost through a perforated floor (14), and overhead air outlets. The novelty is that: (a) air is introduced through an inlet pipe (2, 21, 22, 23) which has a number of inlets; (b) that the inflow of air is controlled by variable throttles or valves (8) located at the air inlets; (c) the space under the perforated floor (14) is sub-divided into a number of chambers; (d) the container cover (16) incorporates a number of air outlets through which air is exhausted, and (e) the inner diameter of the gas inlet pipes (2) narrows towards the respective pipe opening.

Description

The invention relates to a container for composting waste with a air device, an exhaust device and a perforated floor. The invention relates also a gas duct for such a container and a valve for egg NEN such gas duct.

Containers of the type specified are already known. Through the supply air direction is supplied to the room under the perforated floor. On the perforated floor the waste to be composted, which contains organic components, is in Form of a bulk or a pile. The supply air flows through the holes or other openings in the perforated bottom and from there into the Garbage heap. After flowing through the waste, this is essentially bottom-up At the top, the exhaust air from the upper area of the container is exhausted deducted direction. All or part of the waste can be recycled will.

In a known embodiment is located under the perforated floor The only large air box room, in which all perforated floor openings without further tax possibility open.

The object of the invention is to provide an improved container of the entry to propose a way.  

According to the invention this object is achieved in that under the perforated floor Gas guide channel is arranged, which has several outlets. This will created a particularly simple and inexpensive solution.

Advantageous further developments are described in the subclaims.

It is advantageous if the outlets can be opened, preferably by throttles fold down. Then the amount of air can be adapted to whoever the.

Another advantageous development is characterized in that the space or the total air space under the perforated floor is divided into several individual air spaces. Each of these individual air spaces is preferably supplied with air through an outlet strikes, preferably each individual outlet with a valve or a Dros sel flap is provided.

There are several openings in the ceiling of the container for extracting the exhaust air be provided. The number of openings preferably corresponds to the number of Outlets, preferably also having an opening above an outlet is arranged.

It is advantageous if the gas routing channel has a tapering cross section having. This further evens out the flow of the Rotting good reached.

The gas duct can consist of several pipes. This makes it up simple way possible to the gas duct to the required length adapt.

It is advantageous if pipes of decreasing cross-section follow one another. Of the The gas duct then consists of several pipes, the cross-sectional area of which  increasing length becomes smaller. It is possible that the individual tubes in turn have a decreasing cross-section, ie they are conical. However, this is not necessary. The individual raw can cover their entire Length have the same cross-sectional area. It is preferably zy Lindrisch pipes, the diameter of which is the same over the entire length. The the next pipe then has a smaller cross-section or a smaller one Diameter. It is also possible that successive pipes first the have the same cross-sectional area or the same diameter and that pipes with decreasing cross-sectional area or decreasing diameter only afterwards follow again.

The openings in the perforated base preferably run in the flow direction of the Ga tes or air conical. The openings in the perforated base are made as nozzles formed, which means the flow velocity and thus the dynamic pressure be increased so that a greater depth of penetration of the gas or air into the Rotting mixture is reached. It is also advantageous if the holes that are in the loading rich in the side walls of the container, smaller opening cross-sections point as the holes in the middle of the hole bottom. This will make a marginal goose avoidance of air.

According to a further advantageous development, it is provided that the air over a throttle valve flows into the gas duct or air duct.

It is advantageous if the cross section of the gas duct or air duct channel is changeable.

Another advantageous development is characterized in that the valves have an annular portion in which change its cross section the expansion body is provided. The annular section of the valve will flowed through by the air. If the expansion body increases, the Cross section of the annular section reduced. It is possible to expand  Design body so that the remaining cross-section ver is reduced, so the valve is completely closed.

The expansion body is preferably inflatable.

The expansion body can be an annular bead, preferably an inflatable ring bead, be designed.

Another advantageous development is characterized in that the valves an outer part and an inner part each having a cylindrical portion have. The inner part can have a hemispherical lower part. Of the inner part can also have an upper part widening in cross section. This improves the flow through the valve.

A flow meter is preferably arranged in the gas duct. Before it is advantageous if a flow meter is provided for several or all valves see is. The valves can then be assigned as a function of the respectively assigned Flow meter are operated.

The flow meter preferably has a measuring sensor for the static Pressure and / or a sensor for dynamic pressure. This is one Flow measurement possible in a particularly simple way.

A gas duct for a container for composting waste is invented appropriately characterized in that it has several outlets. Advantage it is imprisonment if individual or all of the features described above are provided will.

A valve for a gas duct in a container for composting Waste is characterized according to the invention in that the valves have a ring-shaped Section in which a cross-section changing extent  tion body is provided. It is advantageous if some or all of the above be written further features are present.

Embodiments of the invention are described below with reference to the accompanying Drawing explained in detail. In the drawing shows

Fig. 1 a longitudinal section through a guide die rotting container from a first,

Fig. 2 shows a longitudinal section through a guide die rotting container a second stop,

Fig. 3 is a view of the perforated bottom of the rotting container according to FIG. 2 from above and

Fig. 4 shows a section through a valve and a flow meter accordingly the detail "A" of FIG. 2 in an enlarged position Dar.

In its lower region of the container shown in FIG. 1 1 for composting waste containing organic components has a conical Gasfüh approximately duct or air duct 2, which is arranged below the hole bottom 14. The air is supplied via an end face of the rectangular, elongated container 1 . Correspondingly, the channel 2 runs in the longitudinal direction of the container 1. This is particularly advantageous when several containers are set up next to each other in a system, the loading and unloading of the container taking place from the front side, through a main door 15 .

At the beginning of the channel 2 , a fan 3 is arranged. The supply air flows through the channel 2, which tapers in the longitudinal direction, and from there via a total of four outlets into a respective individual air space belonging to the respective outlet. A throttle valve 8 is assigned to each of the four outlets in the conical channel 2 . The total air space under the perforated floor 14 is divided by transverse to the container longitudinal direction, vertical partition walls 11 into several, namely four individual air spaces, which are acted upon by air, each with a valve 8 provided individual NEN outlets.

This type of air supply can be implemented particularly cost-effectively. You only need a conical channel, which can be designed, for example, as an elongated tube and in which four outlets are provided, each of which is provided with a valve. The space located under the perforated floor 14 can be divided in a simple manner by the said partitions (air space partitions) 11 who the. The partition walls 11 each run from the perforated floor 14 to the bottom surface of the container 1 .

The container has a supply air device, which includes the fan 3 and the fresh air valve 6 . The exhaust air is fed to an air-air heat exchanger 4 , after the exhaust air has passed through it, the exhaust air can be discharged to the outside in whole or in part through the exhaust air valve 7 . The exhaust valve 7 can also be closed, however, to carry all the air in recirculation mode. The circulating air is then fed to an air-water heat exchanger 5 , from where it reaches the duct 2 via the fan 3 . Depending on requirements, fresh air, metered through the fresh air valve 6 , can be supplied.

The rotting mixture 12 rests on the perforated floor 14 , which consists of individual perforated floor plates 9 , as a bed. An air quantity measuring device 13 is assigned to the first valve 8 . The valve 8 can be controlled or regulated depending on the measured value. It is also possible to assign individual or all of the remaining valves 8 an air flow meter.

In the ceiling 16 of the container 1 , four openings for sucking the exhaust air are seen before. For each opening there is a connection duct which opens into an exhaust air duct 10 through which the exhaust air is fed to the air-air heat exchanger 4 . Each opening lies above an associated outlet in channel 2 .

The invention provides a rotting container with a conical air channel running in the longitudinal direction under the perforated floor and with several, individual zones for regulated, controllable air outlets. The air which has passed through the rotting mixture 12 is extracted under the ceiling 16 of the container 1 through the same number of openings as are used as supply air openings or outlets. The air volume is controlled by speed-controlled fans and / or throttles. The outlet openings under the perforated plates 9 in the individual air chambers have valves 8 which can be controlled from the outside. The control signals for the valves 8 come via an air volume measurement 13 in the main air pipe 2 in conjunction with the respective valve 8 . The invention provides a device for ventilation and aeration of rotting material in a closed container, which is preferably heat-insulated. The device can be operated in fresh air mode and / or in recirculating air mode. The perforated base plates 9 can have holes with smaller opening cross-sections in the direction of the side walls of the container 1 than in the middle of the container in order to avoid verge of air.

In Figs. 2 to 4 a modified embodiment is shown. Corresponding components are provided with the same reference numerals so that they do not have to be described again.

Under the perforated base 14 of the rotting container is a gas guide channel 2 angeord net, which consists of several cylindrical tubes 21 , 22 , 23 , each having a circular cross section. In the direction of flow 24 of the air, tubes of decreasing cross-section, that is to say of decreasing diameter, follow one another. The tube 21 has a larger diameter than the tube 22 , and the tube 22 has a larger diameter than the tube 23 . Although the individual tubes 21 , 22 , 23 do not taper, the air duct 2 thus has an overall tapering cross section.

In the example shown in FIG. 2, part of the air duct 2 (in the rearward direction, ie in Fig. 2 to the left, a further, not shown in the drawing part of the air duct 2 connects) are five outlets available. Each outlet is formed by a valve 25 , which is shown enlarged in FIG. 4. The valves each consist of an outer part 26 , which has a lower cylindrical portion 27 and an upper widening portion 28 , and an inner part 29 , which has a hemispherical lower part 30 , a central cylindrical portion 31 and an upper one in the Cross section widening part 32 has. The outer part 26 and the inner part 29 delimit between them an annular section 33 , in which a cross-section changing the expansion body 34 is provided. The expansion body 34 is designed as an inflatable annular bead, which is located in the region of the cylindrical portion 31 of the inner part 29 . A pressure line 35 leads into the inner region of the annular bead 34 . When compressed air is blown into the annular bead 34 via this pressure line 35 , it expands and in this way reduces the annular section 33 . The annular bead 34 can be inflated so far that its outer edge reaches the cylindrical portion 27 of the outer part 26 and abuts there, so that the valve 25 is completely closed.

As seen from Fig. 4, the cylindrical portion includes from 27 of the outer part 26 flush res at the upstream end of the valve 25 with the upper wall 36 of the crude 22nd At the downstream end, the cylindrical section 27 projects into the tube 22 . The lower end of the cylindrical section 27 lies approximately at the same height as the lower vertex of the hemispherical part 30 . This ensures a good and uniform inflow into the annular section 33 . After flowing through the annular section 33 , the air is discharged and fanned out through the widening regions 28 and 32 .

Each valve 25 is assigned a flow meter 37 , which is also shown enlarged in Fig. 4. The flow meter 37 is attached to a base 38 and is located in the middle of the tube 22 . It has an opening 39 on its upstream end face, which is followed by a pressure channel 40 for dynamic pressure (dynamic pressure). At the downstream end of the flow meter, an opening 41 is provided, which serves as a sensor for the static pressure and to which a pressure line 42 connects. The pressure lines 40 and 42 lead to the outside. The flow rate can be determined from the pressures transmitted via these pressure lines.

As can also be seen from FIG. 4, the flow meter 37 has an upstream cylindrical region 43 , which is adjoined by a conical region 44 which widens outwards. The downstream end face 45 is also conical.

Claims (22)

1. Container for composting waste with a supply air device, an air device and a perforated base, characterized in that a gas guide channel ( 2 ) is arranged under the perforated base ( 14 ), which has several outlets. 2. Container according to claim 1, characterized in that the outlets are controllable, preferably by throttle valves or valves ( 8 ). 3. Container according to claim 1 or 2, characterized in that the space un ter the perforated floor ( 14 ) is divided into several individual air spaces. 4. Container according to one of the preceding claims, characterized in that in the ceiling ( 16 ) of the container ( 1 ) a plurality of openings are provided for extracting the exhaust air. 5. Container according to one of the preceding claims, characterized in that the gas guide channel ( 2 ) has a tapering cross section. 6. Container according to one of the preceding claims, characterized in that the gas guide channel ( 2 ) consists of several tubes ( 21 , 22 , 23 ). 7. A container according to claim 6, characterized in that tubes ( 21 , 22 , 23 ) of decreasing cross-section follow one another 8. Container according to one of the preceding claims, characterized in that the openings in the perforated base ( 14 ) in the flow direction of the gas extend ko nically. 9. Container according to one of the preceding claims, characterized in that the gas or the air flows in via a throttle valve in the channel ( 2 ). 10. Container according to one of the preceding claims, characterized in that the cross section of the gas guide channel ( 2 ) is variable. 11. Container according to one of the preceding claims, characterized in that the valves ( 25 ) have an annular section ( 33 ) in which an expansion body ( 34 ) changing its cross section is provided. 12. A container according to claim 11, that the expansion body ( 34 ) is inflatable. 13. A container according to claim 11 or 12, characterized in that the expansion body is designed as an annular bead ( 34 ). 14. Container according to one of claims 11 to 13, characterized in that the valves ( 25 ) have an outer part ( 26 ) and an inner part ( 29 ) each having a cylindrical section ( 27 , 31 ). 15. A container according to claim 14, characterized in that the inner part ( 29 ) has a hemispherical lower part ( 30 ). 16. A container according to claim 14 or 15, characterized in that the inner part ( 29 ) has an upper part ( 32 ) which widens in cross section. 17. Container according to one of the preceding claims, characterized in that a flow meter ( 37 ) is arranged in the gas guide channel ( 2 ). 18. A container according to claim 17, characterized in that a flow meter ( 37 ) is provided for several or all valves ( 25 ). 19. A container according to claim 17 or 18, characterized in that the flow meter ( 37 ) has a sensor ( 41 ) for the static pressure and / or a sensor ( 39 ) for the dynamic pressure. 20. Gas duct for a container for composting waste, thereby characterized in that the gas duct has several outlets. 21. Gas guide channel according to claim 20, characterized by the features egg nes or more of claims 2 to 19. 22. Valve for a gas duct in a container for composting Waste, characterized by the features of one or more of the claims 11 to 16.