DE20121192U1 - Air Cleaner - Google Patents

Description

BBSK0002
D16/D4057
KL/co

Exhaust air purification system

The invention relates to an exhaust air purification system for reducing harmful gases from animal production, such as poultry, duck and pig production.

The exhaust air from animal husbandry contains a variety of air pollutants, including mainly gases, dust and microorganisms. These enter the environment and, in addition to causing considerable odor nuisance, can cause problems such as respiratory disorders and allergies in the population. There is also a great fear of chronic respiratory disease.

With regard to consumer health protection and the prevention of environmental pollution with odorous substances, dust and gases, various exhaust air purification systems are known from the state of the art. The most common system for reducing emissions in animal husbandry facilities today is biological exhaust air purification systems. Two processes are known, namely the biofilter and the bioscrubber.

Basically, both processes are based on the degradation of odorous substances by microorganisms. In the conventional bio-washer, the microorganisms are in the circulating washing liquid. In the biofilter, however, they are fixed to a filter bed made of organic carrier material. The solubility of the odorous substances in the water or in the water film is particularly important here so that microbial degradation can take place.

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Due to the strong change in the concentration of harmful gases in the raw gas due to short cycles, for example in poultry production, conventional biological exhaust air purification filter systems are not suitable because the essential microorganisms cannot be constantly supplied with nutrients. The separation of ammonia, for example, is therefore not possible over longer periods of time without great technical effort and the associated high costs.

Particularly in the area of animal production, very high volume flows occur in the last days of fattening. Disadvantages of the known exhaust air purification systems include the use of conventional filter materials on the one hand and the resulting pressure loss and the uneven flow of the raw gases on the other. Furthermore, the exhaust air must not be contaminated with dust, as dust deposits on the filter material cause even higher pressure losses. In addition, the filter material must be kept sufficiently and evenly moist so that the filter surface does not dry out and the filter effect is lost. To remedy this, irrigation systems are therefore installed, but due to the formation of trickles, these do not moisten the filter material sufficiently, so that the water only partially wets the filter layer.

Another well-known use in poultry farming is a filter wall built into a container, into which the exhaust air is pressed by stall fans. The disadvantage of these systems is the high and uneven filter load caused by the exhaust air blowing directly onto the filter wall. This causes contamination from dust and feathers. The entire surface of the filter wall is therefore subjected to very different loads, resulting in different flow rates and therefore different cleaning performance of the filter surfaces.

The reduction rates for odorous substances such as ammonia are low with conventional exhaust air purification filter systems and can only be achieved at high costs and with increased energy consumption (poor cost-benefit ratio).

It is therefore the object of the invention to develop a system that is able to compensate for fluctuations and to operate independently of the pollutant gas

concentration in the raw gas. Furthermore, it is desirable to upgrade an existing exhaust air duct with the exhaust air purification filter system according to the invention at low cost.

To solve this problem, the invention proposes, starting from a system of the type mentioned at the beginning, that the exhaust air purification system has at least two filter walls loaded with water, whereby these are arranged perpendicular to the incoming exhaust air and parallel to each other and a device for sucking in the exhaust air and, if necessary, for returning it for heat regulation and for increasing the air humidity of the room or stable is connected downstream of the last filter wall.

With the help of the filter walls connected in series, not only are the raw gases freed of dust, feathers or skin abrasion, but the odorous substances excreted by the animals, especially ammonia, are also largely removed. The first filter wall is mainly used to separate solids (e.g. dust, feathers and skin abrasion). The other filter walls, on the other hand, have the task of washing out ammonia and other odorous substances.

By arranging the air intake device at the end of the filter wall series connection, the exhaust air is not blown directly onto the filter wall. The entire surface of the filter wall is evenly and gently exposed to the exhaust air. The exhaust air can therefore flow through the filter wall at a constant rate, which leads to continuous cleaning performance. The filtering effect of the filter walls is thus optimized.

In addition, the device is used to regulate heat and increase the humidity in the stable room.

On hot summer days, stables with animals can heat up very much because the animal heat can no longer be dissipated. This can lead to overheating of the animals and significant failures. In this situation, the device coupled with the cleaning filter system takes over the cooling of the stable building in recirculation mode. The cooling of the air occurs

through the evaporation of water in the filter walls, the so-called evaporative cooling. The device has a relatively high volume flow for this purpose.

On hot summer days, the air in the stable is also dry and often only reaches a humidity level of <40%. The dry air combined with the high temperature leads to the animals' upper respiratory tract drying out. The air is recirculated and the cleaned air is returned to the stable, increasing the humidity in the stable by absorbing water.

The device is conveniently a powerful fan that serves as an air-conditioning and humidifying circulator and/or as an extractor device.

Depending on requirements, one or the other use can be switched or activated, and both uses can also be used side by side. The power is between 0% and 100% for both uses. This means that the higher the power is set in one use, the lower the power in the other becomes.

With this setting option, the stable room can be optimally regulated according to the current climatic conditions, depending on the outside or inside temperature.

In another embodiment, the first filter wall is divided into two walls of equal size, which are arranged one above the other. This allows the separated solids to be removed particularly quickly. The time the solids spend in the filter wall is thus reduced, so that the exhaust air freed of solids can quickly reach the next filter wall and be cleaned. The efficiency of the solids separation is over 90%.

Preferably, the filter layer thickness of the filter walls is 2.5 cm to 50 cm, particularly preferably 10 cm, while the filter surface is 350 m ² / m ² filter wall to 500 m ² / m ² filter wall. With this dimensioning, the volume

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current in relation to the filter area (m ³ /m ² h) is used optimally. The filter area load is relatively high.

In order to increase the effectiveness of the filter, the pressure loss must be kept as low as possible. Therefore, materials that have a high degree of voids and a low tendency to settle (compaction) are preferably used for the filter wall material.

It has been found that particularly biodegradable organic materials, preferably cellulose and particularly preferably cardboard, are suitable for the formation of such a filter wall, whereby these are designed to be waterproof, in particular impregnated. In order to optimize the filtering effect of the filter wall, the filter wall material is further layered on top of one another in such a way that contaminants from the exhaust air are carried along and removed by the flow of water, whereby the partially cleaned air is passed on to the next filter wall.

is a crossed, wavy, lamellar or scale-like structure; other structures are also possible.

With conventional humidification systems by sprinkling the filter material or the filter walls, trickles inevitably form. The water flows partially through the filter layer, so that large dry zones are created on the filter walls, which can lead to reduced filter effectiveness (filter breakthroughs). In the exhaust air purification filter system according to the invention, the filter walls are evenly humidified using submersible pumps. This guarantees that the filter walls are constantly wetted with water. The filter effectiveness, i.e. the separation of solid particles and odorous substances from the exhaust air, is thus increased. Disadvantageous dry zones in the filter wall are almost non-existent.

To ensure even wetting of the filter walls, water pipes are conveniently installed at the top along the entire width of the filter walls. These have openings evenly distributed along the length and directed towards the filter walls, through which the water pumped by the submersible pumps flows from top to bottom in and along the filter walls. Preferably

PE pipes are used, which can be covered with a stainless steel cover.

Another embodiment involves the installation of water storage basins behind each filter wall so that the solids or odorous substances washed away by the water wetting can flow away there without pressure.

In order to improve the collection/collection effect and reuse of the washing water, the water storage basins are divided into individual settling basins in a further embodiment according to the invention, wherein the first water storage basin preferably has at least 3 individual settling basins and the further water storage basins preferably have at least 2 individual settling basins.

Solids are mainly separated on the first filter wall, so that more solids reach the first water storage basin and can settle in the individual settling basins arranged one behind the other. The arrangement of the individual settling basins is such that a larger amount of solids settles in the first individual settling basin and only a few solids settle up to the last individual settling basin. This corresponds to a simplified decanting system.

By connecting the individual settling tanks in series, the last settling tank is only loaded with very few sediments (fine solids). The water from this tank is therefore reused to moisten the filter wall upstream, which is not only cost-effective due to the recycling of the wash water, but also means a reduction in the environmental impact of wastewater.

However, it is also conceivable to use fresh water directly.

Preferably, the water storage tanks and individual settling tanks can be emptied via individual drain valves and/or collecting pipes. This makes cleaning the tanks easier.

To ensure that no washing water gets outside or into the stable building, it is preferable to install at least two overflow protection basins in front of the first filter wall and after the last filter wall.

The spaces between the filter walls and, if necessary, the filter walls themselves can be sprayed with fresh water using spray systems so that the water lost through evaporation is replaced. This significantly increases the ammonia absorption capacity of the water. Other humidification systems are conceivable.

The washing water, in particular the washing water used after the first filter wall, is mixed with acid, preferably acetic acid or sulphuric acid, so that the solubility of the ammonia in the water is increased.

The amount of acids is determined using pH sensors connected to a pH single-channel controller so that the dosing can be automated using a dosing pump and agitator.

However, acidification of the washing water is not absolutely necessary.

The presence of nitrifying bacteria, particularly of the genus Nitrosomonas sp. and Nitrobacter sp. in the water, which can continuously convert nitrite to nitrate, is preferred. The cleaning performance is on average 60%. The cleaning water can be used on agricultural land and therefore reduces the need for mineral fertilizers.

It has also been found that nitrate and methane-degrading bacteria attach themselves to the filter walls and in turn lead to a significant degradation of methane as well.

The exhaust air purification system according to the invention is used to equip existing exhaust air ducts in steel buildings. It is used, among other things, for air conditioning steel buildings. The filter wall material according to the invention is used to produce the filter walls.

The exhaust air purification filter system according to the invention can be used in any stable building for poultry, pigs, cattle, sheep, etc. Good results have been achieved on a trial basis in a duck fattening stable.

To explain the exhaust air purification filter system according to the invention and the filter wall according to the invention, drawings of a preferred system are used below:

Fig. 1 shows an exhaust air purification filter system 1 according to the invention with a first filter wall 10, which is divided into two filter walls of equal size arranged one above the other, and a second filter wall 20. Behind the second filter wall 20, a device 30 is mounted, which enables the exhaust air 50, which is still enriched with harmful gases, to be blown indirectly onto the filter wall. In addition, the device 30 is suitable for releasing the purified air 52 back into the stable building through the recirculation mode for heat regulation and to increase the air humidity.

Submersible pumps 23 are attached to the respective filter walls 10 and 20, in particular also for the divided filter wall 10, which are used to ensure 100% water wetting of the filter wall surfaces. Furthermore, after each filter wall 10 and 20, two water storage basins 11 and 21 assigned to the filter walls are attached to collect the wash water enriched with solids or odorous substances. They can be divided into individual settling basins; these are not shown in the drawing.

Two overflow protection basins 12 and 22 are formed in front of the first divided filter wall 10 and behind the second filter wall 20 to prevent the washing water from entering the stable building.

After each filter wall 10 and 20, two water storage basins 11 and 21 are installed, which are assigned to the filter walls, in order to collect the wash water enriched with solids or odorous substances. They can be divided into individual settling basins; these are not shown in the drawing.

Two overflow protection basins 12 and 22 are formed in front of the first divided filter wall 10 and behind the second filter wall 20 to prevent the washing water from entering the stable building.

The partially cleaned exhaust air 51 between the filter walls 10 and 20 is humidified by means of a spray system 40. The water solubility of the ammonia in the exhaust air can thus be increased.

Fig. 2 shows a cross-section of the upper section of the filter wall 10 (or 20). The filter water flows from top to bottom by means of a pipe 13 with openings evenly distributed along the length and pointing towards the filter wall 10 (not shown). The exhaust air 50 laden with dirt is intercepted by the filter wall 10 and the dirt is carried downwards by crossing water currents 60. This crossing water current 60 results from the filter material structure 70 obtained by the special arrangement of the filter material layers. A stainless steel cover 24 closes off the wall at the top.

- Expectations-

Claims (24)

1. Exhaust air purification system for reducing harmful gases from animal husbandry by means of a washing process, characterized in that it has at least two filter walls loaded with water, these being arranged perpendicular to the incoming exhaust air and parallel to one another and a device for sucking in the exhaust air and, if necessary, for returning it for heat regulation and for increasing the air humidity of the room or stable is connected downstream of the last filter wall. 2. Exhaust air purification system according to claim 1, characterized in that the filter layer thickness of the filter walls is 2.5 cm to 50 cm, preferably about 10 cm. 3. Exhaust air purification system according to claims 1 and 2, characterized in that the filter surface is 350 m²/m² filter wall to 500 m²/m² filter wall. 4. Exhaust air purification system according to claim 1, characterized in that the first filter wall is divided. 5. Exhaust air purification system according to claim 1, characterized in that the device is a fan. 6. Exhaust air purification system according to claim 1, characterized in that the device is designed as an air conditioning/humidity dispenser and/or as an extractor device, wherein the recirculation capacity is adjustable between 0% and 100%. 7. Exhaust air purification system according to claim 1, characterized in that the filter wall material consists of a waterproof impregnated organic material, preferably cellulose. 8. Exhaust air purification system according to claims 1 and 7, characterized in that the filter wall material consists of waterproof impregnated cardboard. 9. Exhaust air purification system according to claim 1, characterized in that a water storage basin is located under each filter wall. 10. Exhaust air purification system according to claims 1 and 9, characterized in that the filter walls are moistened by means of submersible pumps from the water storage basin. 11. Exhaust air purification system according to claim 10, characterized in that water pipes are installed at the top along the entire width of the filter walls for humidifying the same. 12. Exhaust air purification system according to claim 11, characterized in that the water pipes are designed as PE pipes, which are provided with openings evenly distributed over the length and pointing towards the side of the filter wall. 13. Exhaust air purification system according to claims 1 or 9, characterized in that a first water storage basin is divided into at least 3 individual settling basins and further water storage basins are divided into at least 2 individual settling basins, wherein the individual settling basins are arranged one behind the other for solids settling. 14. Exhaust air purification system according to claim 13, characterized in that the water in the last individual settling tank is used to humidify the filter wall connected upstream. 15. Exhaust air purification system according to claim 13, characterized in that the water storage basins and individual settling basins can be emptied via individual drain valves and/or collecting lines. 16. Exhaust air purification system according to claim 1, characterized in that an overflow protection basin is installed in front of the first filter wall and after the last filter wall. 17. Exhaust air purification system according to claim 1, characterized in that fresh water is introduced onto the filter walls and/or into the spaces between the filter walls by means of spray systems. 18. Exhaust air purification system according to claim 1, characterized in that the washing water from the second filter wall is mixed with acid, preferably acetic acid or sulphuric acid. 19. Exhaust air purification system according to claim 1, characterized in that it contains nitrifying bacteria, in particular of the genus Nitrosomonas sp. and Nitrobacter sp., in the water. 20. Exhaust air purification system according to claim 1, characterized in that pH sensors are arranged on the water storage basins. 21. Exhaust air purification system according to claim 1, characterized in that it is installed in front of the side wall ventilation of the stable. 22. Filter wall for cleaning exhaust air, characterized in that it contains organic, biodegradable, waterproof impregnated materials, whereby it has a layered structure. 23. Filter wall according to claim 22, characterized in that the layers have a crossing, overlapping, scale-like, wave-like and/or lamellar structure. 24. Filter wall according to claim 23, characterized in that the material is waterproof impregnated cardboard.