DE102020126472A1 - Room air cleaning device with plasma filter - Google Patents

Abstract

The present invention relates to a room air cleaning device for cleaning room air passed through the cleaning device in a feed-through direction, comprising a particle filter, a plasma filter, a carbon filter and a particulate filter, the particulate filter being arranged behind the carbon filter in the feed-through direction and the carbon filter being arranged behind the plasma filter in the feed-through direction and the plasma filter is arranged behind the particulate filter in the passage direction.

Description

The present invention relates to a room air purification device with a plasma filter. In particular, the invention relates to a room air cleaning device comprising a particle filter, a plasma filter, a carbon filter and a particulate filter.

Out of DE 102018119718 A1 describes a filter with a particle filter, a plasma filter, a HEPA filter and a carbon filter, which are arranged in exactly this order. It was recognized as disadvantageous that the maintenance effort for the individual filter stages was individually different and therefore individual filter stages often had to be serviced. In addition, the HEPA filter stage often required maintenance much earlier than other stages.

The object of the invention was to provide a room air cleaning device with a plasma filter that was easier to maintain and can clean the air more reliably, especially with regard to the ozone content, than in the prior art.

This object is achieved according to the invention by the features of claim 1. Advantageous configurations are specified in the dependent claims.

According to this, the object is achieved by a room air cleaning device for cleaning air passed through the cleaning device in a feed-through direction, comprising a particle filter, a plasma filter, a carbon filter and a particulate filter, with the particulate filter being arranged behind the carbon filter in the feed-through direction and the carbon filter behind the plasma filter in the feed-through direction is arranged and the plasma filter is arranged in the passage direction behind the particle filter.

The particulate filter essentially functions as an air inlet filter for coarse dust. The particle filter removes large particles from the sucked-in room air, in particular fluff from carpets and hair from people and animals. The particle filter can be equipped with lighting to attract insects in the dark. As a protective filter, the air inlet filter for coarse dust extends the service life of the HEPA filter arranged behind it. A stage G4 particulate filter is preferably used.

The plasma filter is preferably a metallic comb or sawtooth ionizer. Ions are generated through the plasma filter using high voltage. Plasma filters or ionizers are devices for the partial ionization of air. The resulting radicals promote chemical degradation processes, which is used to eliminate odors and disinfect. Ionizers work with high voltage, usually several thousand volts and an electrical discharge at peaks or they contain sources of ionizing radiation (ultraviolet emitters, radioactive isotopes). The achievable currents are usually around 1 µA, which corresponds to several billion ions per second. A plasma field and ozone are preferably generated by means of a dielectric barrier discharge with a high energy input of approx. 1,500 volts and a low current of approx. 20 milliamps, which exposes the inflowing air and the particles to a plasma-chemical decomposition process: gases are oxidized, odors are dissolved, germs, colony forming units (CFU), viruses, pollen, spores and bacteria of all kinds are killed and can no longer negatively affect human health.

The charcoal filter preferably comprises activated charcoal. As is usual with filters, the carbon filter filters out undissolved mechanical particles. In addition, the carbon acts as a reducing agent and can absorb oxidizing agents such as ozone and chlorine from the exhaust air. During filtering and adsorption, the substances to be removed are absorbed by the activated carbon and preferably enriched in the carbon mass. In contrast, when reducing ozone, for example, some of the carbon is oxidized to form carbon dioxide and is therefore consumed. The amount of activated carbon is reduced and must be refilled occasionally. The carbon filter is mainly responsible for the fresh, neutral smell that comes out of the device. Ozone O3 is reduced to O2 and other gases are absorbed. The combination of plasma filter and carbon filter results in optimal odor neutralization, including incontinence odors.

HEPA filters are filters for separating suspended matter from the air. They are depth filters and separate particles with an aerodynamic diameter of less than 1 µm, eg bacteria and viruses, pollen, mite eggs and mite excrement, dust, aerosols and smoke particles. In order of decreasing separation effectiveness, HEPA filters are divided into high-performance HEPA filters (ULPA = Ultra-Low Penetration Air), HEPA filters (High-Efficiency Particulate Air/Arrestance) and high-performance particle filters (EPA = Efficient Particulate Air). Glass fiber paper and/or ePTFE membranes with different degrees of permeability or separation are preferably used as the filter medium. Permanently elastic plastic is preferably provided as the casting compound. Gaskets made of different materials and shapes are preferably applied on one or both sides. In addition, HS HEPA filters can also be equipped with a tightness test groove seal and/or cleanable filter media.

Filter mats are preferably used that are mounted in metal frames to enable easy replacement. The filter medium preferably consists of a thermoplastic material such as PTFE (polytetrafluoroethylene) or glass fiber mats with a fiber diameter of about 1 to 10 μm. To increase the filter surface, the mats are preferably built into the frame in a wavy or jagged shape. When changing the filters, this prevents the pollutants that have been separated out from being released and inhaled or touched. For this reason, preference is given to using filter housings that allow contactless filter changes (protective bag change method).

The special advantage of the terminal HEPA filter is that the activated carbon absorbs dissolved particles and thus extends the service life of the HEPA filter. In addition, the risk of the active carbon being metabolized by the terminal HEPA filter is also ruled out in humid room air, as this protects the filter from humidity and the associated risk of bacteria and fungi growing through. In addition, the terminal HEPA filter represents another barrier to particles being blown out into the room air.

In a further advantageous embodiment of the present invention, the particle filter additionally has an activated carbon filter stage. As a result, the particle filter is a combination filter made up of particle filter and carbon filter. These combination filter cells are used for filtration in extraction processes in which particulate and gaseous air pollution must be reliably separated. The preferably compact combination of fine dust or suspended matter filters (HEPA) with activated carbon filter stages on the one hand and the particle filter and the additional activated carbon filter stage on the other hand means that even complex filtration problems can be solved in the smallest of spaces.

The pre-filter designed as a combination filter (particles + activated carbon) ensures that ozone in the room can be sucked in and removed from the air. In addition, the combination filter as a pre-filter represents a further safety level for use in the medical field, since no ozone can flow out of the device even if the blower malfunctions.

In a further advantageous embodiment of the present invention, the room air cleaning device is connected to a fan.

The air can be guided through the room air cleaning device by the blower. The room air cleaning device with the blower can therefore be used as a standalone solution and does not have to be connected to an air duct and integrated there.

The cleaning performance can preferably be regulated by controlling the blower depending on the load on the cleaned room air. For example, when used in a closed room, it is possible to achieve an optimum depending on the rate of air purification quality (air purity at time 2/air purity at time 1) and the total time required to achieve a target air purity by controlling the blower.

The blower of the room air cleaning device can preferably be manually regulated over five stages, but can also be controlled automatically via sensors and regulate itself. The room air cleaning device can be optimally adapted to the requirements of the room air to be cleaned due to the different blower stages, which correspond to different flow rates.

The room air cleaning device is preferably equipped with a sensor system that is set up to detect relevant gases, particles, aerosols and/or suspended particles. The room air cleaning device is preferably also equipped with a control/regulating device which is set up to use the detected measured values to control the room air cleaning device. As a result, the room air cleaning device can always optimally adapt to the conditions of the room or its room air and, for example, initiate special measures.

In a further advantageous embodiment of the present invention, the room air cleaning device comprises a housing, the housing being designed with an air inlet and an air outlet, with the air flowing through the air inlet having a direction of passage through the particle filter (or the combined filter: particle and activated carbon filter) in the plasma filter, into the carbon filter, into the HEPA filter and then into the air outlet.

The air inlet and the air outlet in a housing allow the filter arrangement to be encapsulated between the air inlet and air outlet, thereby preventing air from flowing past the air inlet and the air outlet within the housing.

The room air cleaning device is particularly preferably sealed in such a way that over 99.5% of the air flowing through flows through the terminal particulate filter. As a result of the sealing in particular of the terminal HEPA filter relative to the air outlet, a high level of cleaning efficiency can be achieved, which would not be the case with a terminal activated carbon filter alone. Particularly preferably, the sealing (also) takes place via a tight fit test groove seal.

The HEPA filter preferably includes a HEPA stage, particularly preferably a ULPA stage. A combination of a HEPA level and a UL-PA level can also be provided. An H14 stage is preferably used as the HEPA stage.

The cleaning performance is increased by these terminal HEPA filters in such a way that the room air cleaning device can be used in hospitals and in germ-free areas. In particular, maintenance can also be carried out by protected replacement of the terminal HEPA filter without subsequent contamination and can therefore even be carried out on site.

Further details and advantages of the invention will now be explained in more detail using an exemplary embodiment illustrated in the drawings.

• 1 eine schematische Ansicht einer erfindungsgemäßen Raumluftreinigungseinrichtung

Show it:

• 1 a schematic view of a room air purification device according to the invention

1 shows a schematic view of a room air cleaning device 10 according to the invention. The particle filter 1 is preferably a combination filter made up of a particle filter 1 with an additional activated carbon stage 1.1 (not shown). These filters 1 to 4 are arranged in a housing 8 between an air inlet 5 and an air outlet 6 . The HEPA filter 4 is specially sealed off from the air outlet 6 so that no air that was not previously in the HEPA filter 6 can get into the air outlet 6 . A position for a fan 7 is provided between the particle filter 1 and the plasma filter 2 . An alternative position for a fan is provided between the plasma filter 2 and the carbon filter 3. Fans can also be used in both positions at the same time.

Air is now guided through the air inlet 5 into the housing 8 through the particle filter 1 by the negative pressure that the blower 7 generates at the air inlet 5 . There, the air is cleaned of coarser dust particles and macroscopic objects such as hair, scales, etc. The pre-cleaned air then enters the plasma filter, where a plasma-chemical decomposition process takes place through ionization: gases are oxidized, odors are dissolved, germs, colony-forming units (CFU), viruses, pollen, spores and bacteria of all kinds are inactivated. The air cleaned in this way contains ozone and is passed through the activated carbon filter. There the ozone is reduced back to oxygen and no ozone can get into the room air. A particularly tight seal of the particulate filter 4 relative to the air outlet 6 ensures that only air that has previously passed through the particulate filter can escape. This further increases the quality of the air purification.

With the room air cleaning device according to the invention, a solution has thus been provided which leads to a longer service life of the overall filter arrangement and has an increased cleaning performance.

Reference List

1

particle filter

1.1

Additional activated carbon filter stage in particle filter 1 (combination filter)

2

plasma filter

3

carbon filter

4

HEPA filter

5

air intake

6

air outlet

7

fan

8th

Housing

10

room air purification device

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102018119718 A1 [0002]

Claims (7)

Room air cleaning device (10) for cleaning room air passed through the cleaning device (10) in a through-feed direction, comprising a particle filter (1), a plasma filter (2), a carbon filter (3) and a particulate filter (4), characterized in that the particulate filter ( 4) is arranged behind the charcoal filter (3) in the direction of passage and the charcoal filter (3) is arranged behind the plasma filter (2) in the direction of passage and the plasma filter (2) is arranged behind the particle filter (1) in the direction of passage. Room air cleaning device (10) after claim 1 , wherein the particle filter (1) additionally has an activated carbon filter stage (1.1). Room air cleaning device (10) according to one of the preceding claims, wherein the room air cleaning device (10) is connected to a fan (7). Room air cleaning device (10) according to one of the preceding claims, characterized in that the room air cleaning device (10) comprises a housing (8), the housing (8) having an air inlet (5) and an air outlet (6) being designed, the over room air flowing through the air inlet (5) has a direction of passage through the particle filter (1) into the plasma filter (2), into the carbon filter (3), into the particle filter (4) and then into the air outlet (6). Room air cleaning device (10) according to one of the preceding claims, characterized in that the room air cleaning device (1) is sealed in such a way that over 99.5% of the room air flowing through flows through the terminal particulate filter (4). Room air cleaning device (10) according to one of the preceding claims, characterized in that the HEPA filter (4) comprises a HEPA stage. Room air cleaning device (10) according to one of the preceding claims, characterized in that the HEPA filter (4) comprises a ULPA stage.

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