DE4336081A1 - Process for the conditioning of greenhouse air - Google Patents

Abstract

Process for the conditioning of greenhouse atmospheres, in particular to increase the carbon dioxide content by nonthermally activated mineralisation reaction in the oxidising atmosphere in the presence of photolytically stimulated photocatalysts.

Description

To optimize plant growth or the productivity of plants It is often necessary for houses to determine the carbon dioxide content in the greenhouse air enrich, to a content above that of the natural atmosphere lies and the currently approx.0.035 vol% is approx.0.1 vol%. The optimized Ge greenhouse air should also contain the lowest possible levels of harmful gases, such as B. carbon monoxide, sulfur and nitrogen-containing gases. These are in the natural atmosphere in an urban environment usually over 1 volume ppb for NO + NO₂ and over 1 volume ppb for SO₂ and over 1 volume ppb for COS. These harmful gases can even reach a multiple of the specified values chen. In addition, the greenhouse atmosphere should have the lowest possible Ge stick to biologically active particles such as viruses, fungal spores, bacterial spores, Pollen, etc. included to keep the disease from spreading or uncontrolled to prevent pollination. For the undisturbed plant growth is also a the lowest possible ozone content is advantageous in order to avoid plant damage. The natural air can e.g. B. contain up to 200 volumes of ppb ozone. To the be Particularly undesirable pollutants can also remove those from plants Given biologically active substances, the growth of other plants impair, such as B. the ethylene released by tomato plants and affects the growth of other plants. So z. B. ethylene content for these reasons 4 to 5 ppm not in certain greenhouse crops exceed.

The use of biocides in the greenhouses can lead to an accumulation of these substances come in the greenhouse atmosphere. To the health of the Not affecting employees, it is beneficial to concentrate this  To keep substances in the greenhouse air as low as possible.

With the known technology of thermally activated methane oxidation only the CO₂ content in the greenhouse atmosphere has a positive influence, but not the other problematic contents mentioned. With this method there are also a number of disadvantages, the main of which to be mentioned:

• - Formation of CO, a by-product that is toxic to employees the combustion.
• - Formation of additional nitrogen oxides from the thermally induced reaction between oxygen and nitrogen or ammonia.
• - Formation of ethylene, a gas that has harmful properties may have.
• - Formation of sulfur dioxide from the thermally induced reaction between oxygen and organic / inorganic sulfur components.
• - Need to use high methane gas levels so that ther Mix reaction does not go out.
• - Safety problems due to the use of ignitable mixtures.
• - energy losses due to necessary air exchange with the ambient air, to ver the enrichment of the combustion-related harmful gas contents prevent.
• - No degradation of other contaminants in the greenhouse atmosphere like Ozone, biologically active particles, biocides, pollutants in irrigation water, sulfur dioxide, nitrogen oxides, ammonia, organic and other inorganic sulfur components, odorants.
• - The impossibility of the greenhouse system largely self-sufficient, so possible to operate without supplying and removing material components.

It has surprisingly been found that all of the disadvantages mentioned are due to the inventions process according to the invention for greenhouse air conditioning economically optimal minimal energy consumption can be eliminated.

The Ver driving is that the greenhouse atmosphere with a treatment subjected to photocatalytically activated semiconductor oxides or mixtures thereof becomes. The photocatalytic treatment of air or exhaust air flows for degradation of pollutants in and of itself is known. The use of the method for Conversion of methane or other organic compounds to However, enrichment of the carbon dioxide content has not yet been described been.

Especially the interesting conversion of methane, a natural one Fermentation product to CO₂ is on the photolytically activated photocatalyst relatively difficult to carry out because of its low adsorbability on Photocatalyst and its relatively large inertia. Obviously from these reasons, the photocatalytic degradation to CO₂ has not been described so far been. Furthermore, there is no urgent need for methane degradation Exhaust gases containing pollutants, because low concentrations of methane do not has adverse effects on living nature or humans - aside of the adverse effects of methane as a "greenhouse gas" on the climate. In this respect, the photocatalytic methane conversion to CO₂ according to the invention surprised; Of particular note is the advantage that doped with precious metals Photocatalysts, preferably those doped with platinum metals significantly accelerated methane degradation compared to the undoped photocatalyst takes place, as was surprisingly found. On a felled and at 500 ° C calcined titanium dioxide photocatalyst with anatase structure, with 0.2%  Palladium is occupied, the methane degradation is even 10 times faster than on undoped photocatalyst. The method according to the invention also works the degradation of any greenhouse vegetation pollutants without further ado such as B. ethylene, the content of which in the greenhouse atmosphere lead to damage can.

According to a preferred embodiment of the method according to the invention, the Carbon dioxide content in the greenhouse air measured continuously and as soon as the sinks below a given value, methane gas in the greenhouse air fed. Preferably regardless of where the methane is added, the greenhouse air through the photocatalytically active Reactor passed through the photocatalyst as a fluid bed or as a fixed bed contains. With a methane conversion to CO₂ per passage of the reactor can be much smaller than 100%, e.g. B. only 50% is the methane Greenhouse air conveyed through the reactor.

All other particulate, atomic or moles present in the greenhouse air Kular oxidizable pollutants are in addition to the methane in the aerobic stable mineralization products implemented. Divorce under these conditions the mineralization products on the photocatalyst such as B. sulfuric acid and nitric acid or its ammonium salts, while water vapor and coal dio xid remain in the gas phase. The adhered or sorbed on the photocatalyst According to the invention, acids or salts are discontinuous or continuous Lich removed from the photocatalyst by washing and can be neutralized Form z. B. on irrigation as a mineral plant fertilizer use Find.

Photons with a wavelength of <254 nm wavelength are preferably used to activate the photocatalyst in order to avoid the photocatalytic formation of NO _x and ozone. Ozone, with which the greenhouse atmosphere may be contaminated by exchanging it with atmospheric air, is also broken down on the photocatalyst.

Particulate or containing microbes, viruses, pollen and other organics Drop-shaped phases or gas phases are also from the photocatalyst mined and mineralized. This also includes the vegetation stems mentioned or thermal combustion-derived plant crop pollutants such. B. ethylene.

Because no pollutant production can take place on the photocatalyst the greenhouse atmosphere in a closed circuit with no air exchange Atmospheric air can be operated. This can result in significant energy and Amounts of water can be saved. Corrosion-resistant semiconductor oxides such as, for. B. Titanium dioxide, zirconium dioxide, niobium oxide or tantalum oxide. This is also why particularly suitable because of the photolytically induced charge separation states are particularly stable with these substances. This results in a good one Utilization of photon energy. The process according to the invention turns air into the greenhouses quality achieved, which with regard to the harmful gas or harmful particle concentration far exceeds that of typical clean air areas and therefore also stands out has an outstanding impact on the health of employees. To enrich the photocatalytically formed minerals on the photoka To achieve talysator with mineral salts with fertilizer effect can also be a minor Amount of ammonia are added to the greenhouse atmosphere.

To achieve a closed material cycle system in the greenhouse that can have significant economic advantages, especially where resources are valuable, such as. B. the irrigation water in arid zones, is advantageous in one embodiment of the process according to the invention if the carbon-containing substance components in the greenhouse (CO, CO₂, CH₄, other hydrocarbon-containing gases, plant mass) as completely as possible by means of plant photosynthesis from CO₂ to plant mass, anaerobic fermentation the plant mass to methane, CO₂ and water, aerobic decomposition of the plant mass to CO₂ and water and photocatalytic oxidation of methane to CO₂ and water are converted into one another in a cycle. The feed can be limited to those components that are removed from the system as crops. The gases and ammonia, amines, disulfides, sulfides, mercaptans released during anaerobic fermentation are also converted photocatalytically to sulfate, or nitrate and CO₂ and are returned to the system cycle via irrigation or photosynthesis from the gas phase. According to another variant The method according to the invention can also be done before that the more or less dried biomass is burned from the plant residues, the air-borne combustion products formed such as flue gases and products of incomplete combustion, NO _x , SO 2, aerosols on the photocatalyst being broken down or aerobic be mineralized.

In this sense, it is also advantageous to install the method according to the invention in Ge greenhouses with conventional combustion technology CO₂ generation to the task of breaking down CO, NO _x , SO₂, ethylene, pollen, biocides, bacteria, spores, O₃, etc. . to take over.

UV lamps are preferably used as photon sources. But it can bundled sunlight can also be used. The preferred ones Artificial light sources have a radiation maximum in the wavelength range between 250 nm and 400 nm.  

Many greenhouses have to use groundwater or surface for cost reasons shallow water of insufficient quality are irrigated, the z. B. poorly degradable or toxic chemicals harmful to plants or their degradation contains products. In other cases, the recycled irrigation water can too contain plant-derived biocides, e.g. B. from the underground parts of plants be released into the water. In these cases, the greenhouse air conditioning advantageous with indirect photolytic water treatment get connected. The water pollutants on the photocatalyst can do this bound sorptively or stripped out of the water with air and the stripping air finally together or mixed with the greenhouse air getting cleaned. The sorptive accumulation of pollutants from the Irrigation water can be beneficial simultaneously with the washout Mineralization products happen from the fixed photocatalyst bed.

Claims (6)

1. A process for conditioning greenhouse atmosphere by mineralization reaction in an oxidizing atmosphere, characterized in that the mineralization reaction is carried out as a non-thermally activated reaction in the presence of photolytically excited photocatalysts. 2. The method according to claim 1, characterized in that the greenhouse atmosphere is enriched with methane. 3. The method according to claim 1, characterized in that the addition of methane depending on the carbon dioxide concentration in the greenhouse atmosphere is controlled. 4. The method according to claim 1, characterized in that the greenhouse is operated as a largely closed system by the generated Ab Fall biomass is aerobically and / or aerobically fermented and / or burned, the mineral photooxidation products in the irrigation water phase are solved and only the material shares with the harvested plant parts be taken from the system in the form of mineral and / or organi substances and / or water are returned to the system. 5. The method according to claim 1, characterized in that noble metal doped Photocatalysts for conditioning a methane-containing greenhouse atmosphere can be used. 6. The method according to claim 1, characterized in that the irrigation stripped of water and / or treated with sorption-active photocatalyst and the substances taken up in the stripping gas or those on the photocata  sorptively absorbed substances photocatalytically in the presence of Greenhouse air gas phase can be mineralized.