EP1542786A1

EP1542786A1 - Air transport and/or preparation systems with catalytically coated air elutriating surfaces entering into contact with the air

Info

Publication number: EP1542786A1
Application number: EP03798071A
Authority: EP
Inventors: Hanns Rump; Rainer Klein; Carsten Supply; Jessica Gerhart; Uwe Koziol; Sebastian Neufang
Original assignee: TEM Technische Entwicklungen und Management GmbH; Automotive AG
Current assignee: Automotive AG
Priority date: 2002-09-18
Filing date: 2003-09-17
Publication date: 2005-06-22
Also published as: AU2003275924A1; DE10393817D2; WO2004028668A9; WO2004028668A1; DE10311255A1

Abstract

The invention relates to special catalysts and filters for air elutriation systems, wherein especially ozone and/or air ions of the air which is to be elutriated are mixed for oxidative destruction of organic air contents and bacteria. When catalytic finishes are added to catalytic coatings of surfaces entering into contact with the air, said coatings are more efficient at decomposing ozone and oxidatively destroying oxidizable gases and vapours and organic material. Technical embodiments are disclosed by the invention.

Description

Air transport and / or treatment plants with catalytically coated surfaces in contact with air

There is often a desire to not only clear the air of dusts and particles in ventilation systems of buildings, vehicles, air conditioning units and motor vehicles as well as in compact air conditioning and air conditioning systems, but also to remove odors and, above all, germs (bacteria and fungi) to free. The surface of the evaporator (which is moist during operation) and the filters used in vehicles with air conditioning systems are breeding grounds for all kinds of germs and fungi. Fungi and germs emit a bad smell and are harmful to health.

In DE 195 43 296; DE 196 46 269; DE 196 51 403; DE 199 02 304; DE 199 19 623; DE 199 31 366; DE 199 33 180; DE 100 14485; DE 100 13 841; DE 100 04 326; DE 100 58 476; PCT / DE 00/02164; PCT / EP 01/00672; DE 101 03 905, DE 101 180 78, various methods have been proposed to remedy these problems using ionization and ozonization apparatus.

DE 199 31 366 e.g. A flat assembly with a planar structure has been proposed, which generates advantageous and long-term stable ozone and oxygen ions according to the physical principle of dielectric barrier discharge after application of an electrical high-frequency high voltage.

DE 100 13 841, for example, specifies a method for keeping the ozone and ion production constant with the aid of an electrical control circuit. Because ozone and ion production is subject to a wide variety of influences and also because during long-term operation the electrical and mechanical values of the ozone and ion Change production used assemblies. This has an advantageous effect on ozone and ion production, so that no constant conditions can be achieved without the use of this invention, which is of concern with the known toxicity of ozone.

From DE 100 58 476.4 it is known to understand the production quantity of ozone and oxygen ions as a function of the air quantity and to act on the ozone and ion generator with signals from the central ventilation control device controlling the fans in such a way that a constant concentration even with different air quantities of ozone and ions. This is the prerequisite for controlled and safe functioning of the devices, because if the concentration is too low there is no longer any significant effect and because if the ozone concentration is too high, there will be negative effects on the material involved, without the ventilation effect increasing.

DE 196 51 403.7 proposes an ozone and ion generator in the flow direction upstream of the evaporator in air conditioning systems, e.g. Motor vehicles, buildings or compact air conditioning systems to arrange an ozone and ion source and to flow around the humid evaporator with ozone and air ions. Above all, ozone dissolves in the water on the surface of the evaporator and forms hydro radicals, which have an extremely bactericidal and fungicidal effect and have been tested and reliably prevent any biological activity on the surface of the evaporator. In the direction of flow downstream of the evaporator, a catalyst is proposed which breaks down excess ozone into normal diatomic oxygen. This invention is advantageous for the safe, sterile operation of air conditioning systems of all kinds, in particular those in motor vehicles.

In addition, it was proposed in DE 199 33 180.4 to arrange the ozone and ion source in front of the air inlet and in front of the air filter. This air filter is equipped in such a way that excess ozone is catalytically broken down. DE 101 03 905.0 proposes to enrich the air with ozone and oxygen ions in a tumble dryer, with the result that germs and odor-carrying substances in the (moist) laundry are killed. The complex mechanism of action and in particular the action of ozone dissolved in water (hydroradicals are formed) has been described in more detail. The understanding of these processes is important because water is on all surfaces unc in all materials and this water with added ozone forms hydroradicals, which are extremely effective against bacteria, viruses and fungi as well as odors. In this respect, the teaching of the invention mentioned can also be used very advantageously in general in air treatment plants, because the oxidizing power and thus the bactericidal nature of the monatomic oxygen (Oi) split off in hydroradicals is very much higher than the oxidizing power of ozone O ₃ .

In the abovementioned patent applications, the effect is primarily based on the oxidative chemical effect of the three-atom and one-atom ozone. The proposed solutions to problems make the handling of ozonization devices safer and more predictable. Due to the need to adjust the ozone concentration in the blown air to one of the American Environmental Protection Agency (US-EPA / Environment Protection Agency) and the DIN / EN standard EN 60335-2-65; (1995) to limit the mandatory value so that an ozone level of more than 50ppb can never arise in the rooms thus ventilated, the patent application presented here deals with the beneficial effects of ionized air ions and the technical and safe use of active oxygen ions Compliance with the required limit values.

It is known to ionize air with the aid of high electrical voltages. In principle, ozone is created when there are high-energy discharges in the room (impact ionization). The ionization mostly takes place with the method of coronary discharge (peak discharge). Fine tips protrude into the airspace, which are connected to a high-voltage source. These tips can also be combined into bundles that resemble fine brushes. Metal needles, metal threads, and recently also electrically conductive plastics are known as materials. In front All airborne particles of all types are preferably ionized and therefore carry a negative electrical charge. This electrical charge causes the ionized particles to deposit on surfaces (deposition electrode) in order to release the excess electron there. The result is that the air is freed from particles and germs, which has been used industrially for decades in so-called electrostatic air conditioning devices and dedusting systems.

In the case of apparatuses based on the principle of dielectric barrier discharge, such as, for example, the Siemens tube known since 1857 (Anals der Physik) or the flat module described in DE 199 31 366, both ions and ozone are formed. The chemical reactivity of ozone is higher than the chemical reactivity of oxygen ions. The usefulness of airborne oxygen ions has been described in numerous works and is a principle of nature for cleaning the air from particles as well as for sterilizing air and surfaces.

Since in nature under the influence of ionizing ultraviolet sunlight both mono- and tri-atomic ozone as well as diatomic oxygen ions always arise, it makes sense to use this highly effective and useful principle of nature technically to process air.

In any case, the ozone added to the air flow to be treated must be destroyed before it reaches breathing air. According to the state of the art, this is done by activated carbon filters. It is known to provide filters with chemical admixtures that react chemically with gases that are contained in the air. For example, sodium bicarbonate can chemically bind acidic air components such as sulfur dioxide.

The present invention deals with the problem of improving the efficiency of the catalytically active filter system.

The basic mechanism of action / chemistry for air treatment units with ozone works in several phases. Reactions of ozone with other sub- Due to the low concentration, punching in the gas phase is not often done.

Oxidizable substances (such as CsHι ₈ ) adsorb on surfaces, accumulate to reactive concentrations and react there with active oxygen, ideally to 8 (CO ₂ ) and 8 (H ₂ O). The reaction takes place in particular on the surface of the sorption catalyst arranged in the flow direction after ozonization, which is usually an activated carbon filter.

Active oxygen and ozone dissolve in the water stored in the sorption catalyst / filter and form hydrogen peroxide H ₂ O ₂ and oxygen radicals. Oxygen radicals react violently with oxidizable substances and are extremely bactericidal and fungicidal (concentrations of 1-5ppm active oxygen dissolved in water are sufficient). The half-life of oxygen radicals stored in the sorption catalyst can be up to a few days. Contamination of the A-carbon filter is reliably prevented and airborne bacteria and germs are destroyed. This is because the chemical oxidation process continues even after the ozone supply has ended.

Stored oxidizable gases or vapors as well as adsorbed bacteria and fungi are broken down or find no environment for spreading. The moisture stored in the activated carbon (sorption catalyst) plays an important role that has so far been neglected. In pipes and air ducts there are comparable sorption and thus agglomeration effects on the surfaces. There are locally very high concentrations of both fractions, which enables a chemical reaction between active oxygen ions and oxidizable gases or vapors. (VOC = volatile organic compounds)

It is known that active oxygen ions together with that in the filter or on

Moisture present on the surface (these are a few molecular layers on the entire surface of the activated carbon) forms hydroradicals. Intermediate steps stands for the highly radical monatomic oxygen ions, the reactivity of which is once again greater by a factor of 1000 than that for the atomic oxygen ions.

This reaction mechanism takes place on the surface of the catalyst or the surfaces of the air channels and is the reason that it is possible to work with relatively much lower concentrations of active oxygen ions than purely stoichiometric considerations suggest. Part of the ozone dissolves in the water, which is present practically everywhere on all surfaces, for example in activated carbon air filters (max. 4.94 ml (corresponds to approx. 10 mg) ozone dissolves in 1000 ml of water).

Highly reactive hydro radicals (OH) or hydroperoxy radicals (O ₂ H) are formed:

1st stage O3 - ► O (1 D) + O2

2nd stage U (IU) + M iU ^ n Uιr Il_ + _L D-Mπ i

3rd stage OH + O3 - ► H2 = + O2

In the subsequent oxidation, organic compounds are oxidized more and more in multi-stage reactions with the formation of so-called peroxy radicals O ₂ R (R = organic residue), bacteria and viruses are destroyed or biologically passivated / denatured.

Germs, protein residues and odor-carrying chemical substances (organic substances) attached to the sorption catalyst are advantageously oxidatively destroyed or denatured. The sorption catalyst remains permanently hygienic and olfactory.

The above-mentioned effects are intensified if, in addition to, or in addition to, or as an alternative to activated carbon, catalytically active substances are used. In principle, catalytically active substances can be mixed with the activated carbon and can be used together as filter material. It is also possible to have catalytic activity on the upstream side of the activated carbon filter Apply material as a layer. Finally, it is possible to apply a layer of the catalytically active material on the outflow side of the activated carbon filter.

According to the invention, all transition metals and their compounds can be considered as catalytically active material. The following have also been tried and tested as a catalytically active substance:

• Silver, platinum, palladium, vanadium, tungsten

Salts or oxides or compounds of these substances have also been tested as catalytically active, for example

• Palladium chloride, tungsten trioxide, vanadium titanate.

Non-noble metals are also catalytically active if chemical energy in the form of e.g. Ozone is supplied and the reactions supported:

• Iron, nickel, copper, tin and zinc, and their chemical compounds, especially their oxides. • Titanium and titanium dioxide have good catalytic properties.

In an exemplary embodiment of the concept according to the invention, titanium dioxide (TiO ₂ ) is applied to a suitable carrier as a gas-permeable coating on the outflow side of an activated carbon filter. The catalytic activity of titanium dioxide is stimulated by the chemical energy that is inherent in ozone and air ions. Oxidizable material such as odor-bearing gases or vapors as well as organic material such as bacteria and viruses are advantageously destroyed on the surface of the catalyst. Gases such as nitrogen oxides, sulfur dioxide, phosphorus dioxide and other reducible gases are catalytically reduced. The ozone content in the air is reduced to an innocuous minimum. Since the titanium dioxide used in the example works as a catalyst and is not involved in the chemical process itself, there is no wear that shortens the life of the sorption catalyst. Rather, the outflowing air maintains its neutral character.

FIG. 1 shows an example of a typical air treatment system, such as that used in vehicles, in compact air treatment devices and in building air conditioning systems Commitment comes. A pre-filter 1 is shown, which retains dusts and particles. The particle filter plays no role in the functional context of this invention. Furthermore, an air-promoting blower 2 is shown, which of course can be arranged elsewhere within the functional series. The ozone and ion generator 3, which enriches the air with a certain amount of ozone, is also shown. Concentrations between 50-200μg / m ³ are typical for applications in the field of air treatment. In addition, an activated carbon filter 4 is shown, which also serves as an ozone converter and as a simple catalyst and is therefore called “sorption catalyst”.

FIG. 2 shows a structure which is identical in principle, but is supplemented by the catalyst 5. The catalyst 5 in one embodiment of the invention consists of catalytically active material, for example titanium dioxide (TiO ₂ ). The catalyst can be applied to its own, air-permeable carrier layer and can be attached as a separate component behind the activated carbon sorption catalyst 4. The catalyst 5 can also be adhered to the outflow side of the sorption catalyst 4. The catalyst 5 - not shown in the picture - can be contained in the activated carbon sorption catalyst 4 as a mixture of the activated carbon. The catalyst 5 can - not shown in the figure - be adhered to the upstream side of the activated carbon sorption catalyst 4 or can be arranged as a separate component on an air-permeable carrier layer in front of the active sorption catalyst.

There are often so-called combination filters in motor vehicles, which both retain dusts and particles as a particle filter and also retain unpleasant odors - such as exhaust gases - as an activated carbon filter. Even without a technical ozone source, when using these filters in certain weather conditions there is a natural mechanism of action similar to that described above. This is because the natural ozone or a high number of ions in the outside air is occasionally contained in more or less high, strongly fluctuating and regionally different concentrations. In the case of occasionally higher ozone concentrations, the activated carbon filters actually act as sorption catalysts and break down airborne ozone, which benefits the health of vehicle occupants, because ozone is a respiratory poison.

According to the invention, it is additionally proposed to combine air filters used in automobiles with catalysts in the sense of this invention. The aim is to maximize the depletion of natural ozone and to maximize the useful processes taking place in conjunction with ozone and air constituents and to optimize the service life of the filters.

According to the invention, it is further proposed to provide activated carbon filters for air conditioning tasks of all kinds with catalytically active substances in the sense of the invention presented here, in order to improve the efficiency of the filters against oxidizable air components beyond the pure absorption of the activated carbon and to reduce oxygen radicals in the Reliably destroy breathing air.

In one embodiment of the invention, a catalytically active material, for example titanium dioxide, is applied to the surface of evaporators in air conditioning systems, which can be located, for example, in buildings, in compact devices or in automobiles. A small amount of ozone is added to the airflow that is directed to the evaporators. If ozone comes into contact with the catalyst, the chemical reactions described above intensify. This makes it possible to effectively prevent the known dangerous and unpleasant contamination of the evaporator with the help of gassing with ozone and active oxygen ions in a very low concentration. The ozone contained in the supplied air is broken down on the surface of the fumigated evaporator and thus extracted from the air. The evaporator itself functions here as the sorption catalyst described above.

As sorption catalysts with a particularly low flow resistance are in

DE 100 04 326 technical devices have been described which have large-area plates coated with activated carbon, which are aligned parallel to the flow. On the surface that has been massively enlarged with the help of activated carbon adsorb air and bacteria, as well as ozone. On the one hand, the reaction mechanisms described above lead to ozone depletion and destruction of VOC and bacteria, viruses and fungi and their spores.

According to the invention, it is proposed to add at least one of the catalytically active materials described above to the activated carbon coating. The result is advantageously that the efficiency for the degradation of (zon as well as for the oxidative destruction of VOC, bacteria and viruses is increased significantly.

It is also proposed that indoor air ducts with, for example, titanium dioxide; Coating because the surfaces of climate channels adsorb air constituents If small amounts of air ions and / or ozone are introduced into the climate channels at the same time, they will also adsorb on the surfaces.The chemical reaction described above sets in and is catalytically strengthened with the result that the transported air is free of ozone, oxidizable gases and vapors and bacteria, viruses, fungi and their spores. This would make an important contribution against the so-called "sick building syndrome".

The invention extends not only to the aforementioned examples but we are used wherever in the interaction of air, ozone, air ions and air contents such as gases, vapors, bacteria, viruses, fungi, spores of the effect? degree of the reaction mechanisms described in principle is to be improved.

11

12

Claims

claims

1. Air treatment and air conveying system, consisting of a transport duct for air, blower for transporting air, inlet and outlet for air, whereby technical facilities for generating air ions and / or ozone and their introduction into the air stream may be present, technical facilities for cooling, heating or humidifying the air, technical equipment for mechanical filtering of the air may be present, activated carbon filters for absorbing organic vapors or gases in the air duct, characterized in that air-contacting surfaces with catalytically active material are entirely present or are partially coated, which in the presence of reducible gases initiates and / or accelerates chemical reactions with oxidizable or organic material.

2. Air treatment and air conveying system according to claim 1, characterized in that one or more activated carbon filters are arranged in the air flow for absorption of oxidizable or organic vapors, gases or bacteria and / and that in the flow direction upstream of the activated carbon filter (s) is an air-permeable carrier material is arranged, which is coated with a catalytically active material.

3. Air treatment and air conveying system according to claim 1 or 2, characterized in that activated carbon filters are arranged in the air flow for absorption of oxidizable and / or organic vapors, gases or bacteria / viruses, and that an air-permeable carrier material is arranged in the flow direction after the activated carbon filter, which is coated with a catalytically active material.

4. Air treatment and air conveying system according to one of claims 1 to 3, characterized in that activated carbon filters for absorbing oxidizable and / or organic vapors, gases or bacteria / viruses are arranged in the air flow, the activated carbon being admixed with a catalytically active material.

5. Air treatment and air conveying system according to one of claims 1 to 4, characterized in that an evaporator is attached for the purpose of cooling in the air flow, the surfaces of which are coated with a catalytically active material.

6. Air treatment and air conveying system according to one of claims 1 to 5, characterized in that air-transporting air conditioning channels are coated on the inside with a catalytically active substance.

7. Air treatment and air conveying system according to one of claims 1 to 6, characterized in that transition metals and their catalytically active compounds are used as the catalytically active material, such as platinum, palladium, vanadium, tungsten.

8. Air treatment and air conveying system according to one of claims 1 to 7, characterized in that non-noble metals such as iron, copper, nickel, tin, zinc, titanium or alloys of these metals and / or their oxides are used as the catalytically active material.