NL2011418C2 - FOR CLEANING AMMONIALLY POLLUTED AIR FURNISHED ROOF, WHEN THE AIR IS DIRECTED ALONG THE PLANTS. - Google Patents

Description

For the cleaning of air that is contaminated with ammonia, the roof is guided along the plants

The present invention relates to a device for cleaning air contaminated with ammonia, comprising a substrate on which ammonia-absorbing plants grow and air-guiding means for passing the air contaminated with ammonia along the plants.

Such devices are known, inter alia, from agriculture, where they are used to remove ammonia from the gases supplied with stables. After all, the fertilizers produced by livestock form ammonia, which is harmful to the environment, so that, partly to comply with legal requirements, the emission of ammonia must be reduced. It is known that plants and micro-organisms living on the plants convert ammonia into nitrogen and water. It is therefore known to pass ammonia-containing gases through such plants to reduce ammonia emissions. According to such methods, the ammonia is led through the leaves and stems of the plant, since the roots are in or under the substrate. With this prior art method, although a considerable part of the ammonia is absorbed by the plants and converted, a remaining part of the ammonia remains in the air.

The object of the invention is to provide a device that removes a larger part of the ammonia present in the air.

This object is achieved by a device of the above-mentioned type, wherein the plants extend through the substrate, the roots of the plants extend at least partially below the substrate and the air-guiding means are adapted to guide the plants along the roots of the plants. air contaminated with ammonia. Because the air is now passed along the roots of the plants, a more intimate contact takes place between parts of the plants and the air. Furthermore, the chemical conversion in question takes place in the roots or in microorganisms present on the roots, so that the conversion is more effective since no transport of the ammonia through the plant need take place. Another advantage of this device is that the substrate, in which the plants are anchored, is often provided with water so that ammonia is formed through contact between water and ammonia, which is easier to stay in place than air and which can thus be converted in phases by the roots. , or the microorganisms living thereon. It is noted here that the air does not necessarily come from stables, but that the invention also applies to air originating from other sources, contaminated with ammonia.

According to a first embodiment, the substrate extends over a surface with a considerable horizontal component and the air guide means are adapted to cause the contaminated air to flow under the substrate. Although it is not excluded that the plants are anchored in a substrate with a vertical component, it is easier to use the property of most plants to grow towards the light, i.e. upwards, and the substrate extends substantially horizontally. to stretch.

In principle, it is possible to support the substrate over its vast majority of its surface. The requirements for the support are considerably lower when the substrate has a rigid structure in which openings are provided through which the plants extend. This creates more freedom for the structure of the guide means for guiding the air along the underside of the substrate. The substrate can therefore also be formed by a plastic grid.

The air gel means preferably comprise a structure defining mutually parallel cleaning channels, air supply means leading to the cleaning channels and air discharge means directed from the cleaning channels to the environment. After all, this is a simple structure that, with suitable design of the air supply means, leads to a good distribution of the air.

In order to keep the cost of the device as low as possible, another embodiment proposes that the structure defining the cleaning channels is formed by corrugated plate, the cleaning channels being enclosed between the substrate and the corrugated plate.

The plants will obtain a substantial part of their nutrients by absorbing ammonia from the air. The plants also need water, partly to compensate for water evaporating from their leaves, and partly for their metabolism. To this end, the device is preferably provided with water supply means for supplying water to the plants.

These water supply means can take various forms, such as nozzles directed at the substrate, but it is structurally attractive when the water supply means are adapted to supply water to the cleaning channels.

As explained above, livestock houses and poultry houses are important sources for air contaminated with ammonia. It is therefore attractive to connect the air supply means to a shed, such as a poultry or pig shed.

To reduce the space occupied by the device, it is preferable that the device is placed on the shed. This, of course, is based on the presence of a sufficiently strong roof. However, if there is a roof covered by corrugated sheets, it is particularly attractive if these corrugated sheets form at least a part of the structure forming the cleaning channels.

According to a more specific embodiment, the roof is inclined at an angle of inclination between 10 ° and 45 ° and the air supply means are connected to the lower edge of the roof and the air discharge means are connected to the upper edge of the roof. This makes use of the natural draft within the structure on the roof. The warm air from the stable will, after all, increase its low density, whereby heat loss is prevented by the sun's radiation on the roof. Incidentally, it is also possible to use such a supply and discharge system with other roof slopes.

The relevant slope angle is optimized for airflow, but the supply of water is more difficult because at this slope angle the water flows directly downwards and hardly has the opportunity to be absorbed by the roots of the plants. However, when a structure provided with transverse elevations is arranged on the bottom of the cleaning channels, a series of reservoirs is created one behind the other in which the water remains and can be absorbed by the plants.

Depending on the emission of air contaminated by ammonia from the shed, which, incidentally, also depends on the nature of the animals present in the shed and its density, it will not be necessary in all cases to cover the entire surface of the roof with a device according to the invention. According to a preferred embodiment, the roof is therefore partly covered with the substrate.

In such a situation, the cleaning channels will therefore often extend over the entire roof.

In order to make useful use of the roof in such situations, the part of the roof that is not covered with substrate is preferably provided with a device for the useful use of the solar energy affecting that part of the roof. The relevant part of the roof can be covered with photovoltaic cells or with heat exchangers for transferring solar heat to fluid flowing through the heat exchangers.

According to a further preferred embodiment, the roof is a saddle roof and the substrate is arranged on the roof part that is mainly facing the sun.

In order to enhance the already described rising movement of the air through the cleaning channels, it is preferable for the air discharge means to be connected to the lower end of a substantially vertically extending discharge channel.

The temperature in the stable often deviates from the temperature of the environment. The air to be supplied to the shed to equalize the air leaving the shed must therefore be heated or cooled in order to keep the temperature in the step constant. It is therefore attractive from an energetic point of view to provide a cover plate under the corrugated plates which encloses air channels extending parallel to the cleaning channels between the corrugated plate and the cover plate and that the air channels are connected at one of their ends to the environment and at their other end are connected to the interior of the house. Hereby an effective thermal transfer takes place between the two air flows.

In order for the energy transfer between the exiting air and the incoming air to take place as effectively as possible, it is preferable for the air ducts to be connected to their sheds at their lowest end and to the surroundings at their highest end. The direction of the air flows is then reversed, so that the counterflow principle is applied.

Next, the present invention will be elucidated with reference to the accompanying drawings, in which:

Figure 1: a schematic detailed cross-sectional view of a structure according to the invention;

Figure 2: a schematic perspective detail view of a variant of the structure shown in Figure 1;

3; a schematic sectional view of a shed, this is provided with a roof according to the invention;

Figure 4: a schematic detailed cross-sectional view of the structure according to Figure 3; and

Figure 5: a view corresponding with figure 3 of a different embodiment.

As already stated in the preamble, the invention relates to directing the ammonia-containing air via the roots of the ammonia-absorbing plants. To this end, the device shown in Figure 1 comprises a substrate 1, which is formed by a plate made of a sturdy plastic such as ABS, which is provided with holes 2 arranged in a regular pattern. The plants 3, often but not necessarily of the Sedum genus, extend through the holes 2, the leaves 4 of the plants 3 being above the substrate 1 and the roots 5 of the plants 3 being below the substrate 1 are located. The space 6 below the substrate 1 is closed at its bottom by a plate 7. Air containing ammonia is supplied to the space 6 by means of a supply line 8 and air leaving the space, part of which the ammonia is absorbed by the plants, leaves the room via a discharge channel 9. An air pump can be used for this, but it is also possible to make use of other means for moving air such as a natural draft.

Figure 2 shows a similar situation, in which the flat plate 7 in figure 1 has been replaced by a corrugated plate 10. In figure 2 - for clarification - the plants 3 are not shown. The corrugated plate 10 comprises crests 11 and valleys 12, which extend parallel to each other. The substrate 1 here rests on the tops 11 of the corrugated plate 10. The troughs 12 of the corrugated plate 10 here form cleaning channels 13. These cleaning channels 13 distribute the air over the entire surface of the device, whereby an even distribution of the air over the roots 5 of the plants 3 is obtained and the effectiveness of the absorption is optimized. Incidentally, it is possible to leave space between the tops of the corrugated sheets and the substrate. It is also possible to use a plate with a structure that forms a different cleaning channel than a corrugated plate. The holes can of course be round or have a different shape than the drawn square holes.

The device can simply be placed on the bottom. Such a solution can be applied when sufficient space is available. In many cases the space is limited. It is then attractive to place the device according to the invention on the roof, for example on the roof of a shed. The ammonia-containing air from the shed can then be treated on the roof of the shed to reduce the amount of ammonia. Such a situation is shown in figure 3. This figure shows a stable 15, which is provided with a gable roof of which only a part is visible. The visible part of the gable roof comprises a sloping part 16, corrugated plates 10 being arranged on roof trusses 17 of the sloping part 16. The substrate 1 with the plants 3 is placed on the corrugated plates 10 by means of fastening means which preferably do not extend through the corrugated plates. The valleys and tops of the corrugated plates 10 extend from top to bottom, as is common with roofs to allow drainage of rainwater. On the underside, in the vicinity of the wall 18 of the shed, a slot 19 is provided for supplying air from the interior of the shed 15 to the cleaning channels 13. At the ridge of the roof is a vertically upwardly extending exhaust duct 20 is provided for discharging the cleaned air. It is now assumed that the air leaving the shed is warm, so that a sufficiently large air flow is obtained by means of chimney action. The heating of the air by the sun shining on the roof also plays a role in this.

If this natural draft is not strong enough to generate a desired flow, a fan can be used.

The plants 3 not only need ammonia for their survival, but also water, not only to compensate for water evaporating on the leaves 4, but also for assimilation. In the case of the corrugated plates 10, the supply of water through the valleys 11 is in principle well possible from above, but with the oblique placement of the corrugated plates 10, the water will drain away quickly, so that it is difficult for the roots 5 of the plants 3 to have water. In order to avoid this problem, when the corrugated plates 10 or other channels form oblique plates, plates 21 are placed in the cleaning channels, which retain the water in the manner of a dam. Figure 4 for this purpose preferably shows partitions 21 made of plastic, which are placed at regular distances in the cleaning channels 13 and which can be mutually connected, parts of which are not shown in the drawing, the plastics determining the mutual distance. The height of the partitions 21 is dependent on the angle of inclination of the corrugated plates 10, so that the roots 5 of each of the plants 3 can reach the water. Incidentally, it is also possible to install nozzles to feed the water to the plants 3 from above. It is also not excluded to supply the water via the substrate 1 designed for this purpose.

As has already been explained in the preamble, it is attractive to thermally bring the air discharged from the shed into contact with the air to be supplied to the shed to compensate for thermal loss. This applies both when the outside temperature is higher than the temperature in the house when it is lower. The relevant embodiment shown in Figure 5 comprises a second plate 23 below the corrugated plate 10, so that a space is created between the plates 10 and 23. The second plate herein preferably rests on the trusses 17. The elongated spaces between the plates 10, 23 form air ducts 24. At their upper side, the air ducts 24 are connected to a supply duct 25 of outside air. The supply opening of this supply channel 25 must be situated at a distance from the discharge opening of the discharge channel 10 to prevent suction of discharged air. This outside air is then supplied to the interior of the shed 15 via the air ducts 24 and a pipe 26. Since these fresh air air ducts 24 are only separated by the corrugated plates 10 from the air ducts 13 for the air to be discharged, heat transfer takes place easily. It will be clear that it is also possible to use different types of configurations.

It is clear that the above description is not to be construed as limiting, that the measures according to the various embodiments can be combined and that the scope of protection is determined by the claims.

Claims (18)

Claims 1. Apparatus for cleaning ammonia-contaminated air, comprising a substrate in which ammonia-absorbing plants grow and air-conducting, and for passing the air contaminated with ammonia along the plants, characterized in that the plants pass through the substrate extend that the roots of the plants extend below the substrate and that the air guide means are adapted to guide the air contaminated with ammonia along the roots of the plants. Device as claimed in claim 1, characterized in that the substrate extends over a surface with a considerable horizontal component and that the air guide means are adapted to cause the polluted air to flow under the substrate. Device as claimed in claim 1 or 2, characterized in that the substrate is a rigid substrate, in which openings are provided through which the plants extend. Device as claimed in claim 1, 2 or 3, characterized in that the air guide means comprise a structure defining mutually parallel cleaning channels, air supply means leading to the cleaning channels and air discharge means directed away from the cleaning channels and directed to the environment. Device as claimed in claim 4, characterized in that the structure defining the cleaning channels is formed by corrugated plate and that the cleaning channels are enclosed between the substrate and the corrugated plate. Device as claimed in claim 5, characterized in that the device is provided with water supply means for supplying water to the plants. Device as claimed in claim 6, characterized in that the water supply means are adapted for supplying water to the cleaning channels. Device as claimed in claim 4, characterized in that the air supply means are connected to a shed, such as a poultry or pig shed. Device as claimed in any of the claims 5-8, characterized in that the device is placed on the stable and in that the structure forming the cleaning channels is formed by corrugated plates serving as the roof of the stable. Device as claimed in claim 9, characterized in that the roof is inclined with an angle of inclination between 10 ° and 45 ° and that the air supply means are connected to the lower edge of the roof and the air discharge means to the upper edge of the roof. Device as claimed in claim 10, characterized in that a structure provided with transverse elevations is arranged on the bottom of the cleaning channels. Device as claimed in claim 10, characterized in that the roof is partially covered with the substrate. Device as claimed in claim 12, characterized in that the cleaning channels extend over the entire roof. Device as claimed in claim 12 or 13, characterized in that the part of the roof that is not covered with substrate is provided with a device for the useful use of the solar energy affecting that part of the roof. Device as claimed in any of the claims 10-14, characterized in that the roof is a saddle roof and that the substrate is arranged on the roof part that is mainly facing the sun. Device as claimed in any of the claims 10-15, characterized in that the air discharge means are connected to the lower end of a substantially vertically extending discharge channel. Device as claimed in any of the claims 9-16, characterized in that a plate is arranged under the corrugated plates which encloses air channels extending parallel to the cleaning channels between the corrugated plate and the plate and that the air channels are connected at one of their ends with the environment and at their other end are connected to the interior of the stable. Device as claimed in claim 17, characterized in that the air ducts are connected to the shed at their lowest end and are connected to the environment at their highest end.