DE102022113345A1 - disinfection unit - Google Patents

Abstract

The object of the invention is to create an air cleaning arrangement for cleaning or sterilizing air, which allows for a simple structure and also works efficiently. Furthermore, a maintenance-friendly construction should be created.1. Air cleaning arrangement (7) comprising at least one air cleaning housing (7a), wherein the at least one air cleaning housing (7a) has at least one air inlet opening (4) and at least one air outlet opening (5) and in the at least one air cleaning housing (7a) at least one UV light source (8) and at least one electrical field (9) generated by means of high voltage is present, with air being able to flow through the at least one air inlet opening (4) into the at least one air cleaning housing (7a) and at least in regions in the air flow the at least one UV light source (8) and the at least one electric field (9) is arranged and the air can flow out of the at least one air cleaning housing (7a) through the at least one air outlet opening (5).

Description

The invention relates to an air cleaning arrangement for cleaning or sterilizing room air, with viruses, microscopic creatures and bacteria being eliminated or at least rendered harmless in the room air by means of UV light and high voltage during room air circulation through the air cleaning arrangement. The air cleaning arrangement is intended for different uses of space, such as in living rooms, offices, consultation rooms or consultation spaces or in vehicles. The air cleaning arrangement can be used in different ceiling or wall or room structures. Use in lighting or lighting concepts is also possible.

It is known from DE 10 2013 225 255 A1 a multifunctional ceiling light, which has an air purification device by means of a UV radiation device.

Also known are air cleaning arrangements that only work by means of UV light.

The object of the invention is to create an air cleaning arrangement for cleaning or sterilizing air, which allows for a simple structure and also works efficiently. Furthermore, a maintenance-friendly construction should be created.

With the invention it is achieved in the specified application that an air cleaning arrangement is created, the air cleaning arrangement comprising at least one air cleaning housing. At least one air inlet opening and at least one air outlet opening are present in or on the at least one air cleaner housing. Furthermore, at least one UV light source and at least one electrical field generated by means of high voltage are present in the at least one air cleaning housing. Air can flow into the at least one air cleaner housing as an air flow through the at least one air inlet opening and can flow out of the at least one air cleaner housing through the at least one air outlet opening. The at least one UV light source and the electric field are arranged in the air cleaner housing in such a way that they are arranged in the air flow at least in certain areas and are therefore surrounded or flowed around by the air at least in certain areas, i.e. the air flow is at least partially or completely covered by the UV light of the at least a UV light source and is detected by at least one electric field.

Depending on the configuration, areas of still air are also provided or possible in the air cleaning arrangement or form.

This compact structure can be advantageously arranged in walls or ceilings, ventilation ducts or lamp housings in a room or vehicle. For example, medical, school, private or public rooms, consultation rooms, cells, waiting rooms, restaurants or museums cannot be considered as rooms or premises. Vehicles can, for example, not exclusively be cars, buses, trains, airplanes. In summary, we speak of air or room air.

The at least one air cleaning arrangement can be arranged alone or in ventilation ducts that are provided for this purpose or are already present. However, the at least one air cleaning arrangement can also be part of a ventilation duct. Likewise, the ventilation duct can form part of the respective air cleaning arrangement.

Ventilation ducts can have different cross-sections. Accordingly, the at least one air cleaning arrangement or its at least one air cleaning housing can also have different cross sections.

In this way, different cross sections of the air cleaning arrangement and/or the ventilation ducts can also be combined in the course of the air flow. A transition from a round ventilation duct to a round air cleaning arrangement or vice versa is also possible.

According to the invention, a simple structure is achieved which also effectively eliminates viruses, microscopic creatures and bacteria in the respective room air by means of UV light and high voltage.

The basic principle of the technology is the suction of air, which is contaminated by viruses and bacteria, for example, through corresponding electrically operated blowers or fans.

The air is accordingly transported or moved via or by means of a blower or flows into and through air ducts and/or the at least one air cleaning housing. The fan can be a fan already provided for ventilation.

It can be advantageous that there is at least one fan for or on the air cleaner housing, with the at least one fan being arranged inside and/or outside of the air cleaner housing and/or that the at least one fan in the area of the air inlet opening or the air outlet opening is arranged. This favors the flow behavior or the effect of the air cleaning arrangement.

Blower or fan are to be understood as synonymous, so that only one of the terms is used in the following and the term not mentioned is therefore also included.

Depending on the design, for example, axial fans or radial fans or tangential fans can be considered as blowers or fans.

All areas of ventilation or air circulation through which the air or the air flow can flow or get can be considered as an air duct or air duct section. The air duct or the air duct section can also be defined by at least one of the air cleaner housings or by the at least one fan.

The at least one air cleaner housing can be assembled in one piece or in several pieces. Insulating or isolable materials such as metal, plastic and wood and composite materials as well as combinations of at least the materials mentioned and other suitable materials come into consideration as the material. For example, edged, welded, glued or deep-drawn, milled and sprayed or printed metal parts or plastic parts or wooden parts come into consideration. Groups, combinations or arrangements of several parts are also possible and are not based, for example, exclusively on the design requirements made and the area of application.

The at least one air duct or the at least one air duct section can enclose or adjoin the at least one air cleaner housing, so that a continuous or closed air flow area is formed.

It is thus also provided that the at least one air cleaner housing is also the air duct or forms it, depending on the design, without the at least one air cleaner housing being surrounded by a separate air duct.

Separate air cleaning arrangements, comprising at least one air cleaning housing with at least one fan apart from an air duct or ventilation or in addition to an air duct or ventilation, are also possible.

In at least one air cleaner housing, depending on the design, one or more air currents are directed across a high-voltage electrical field, which is preferably generated by means of a DC voltage, for example between plates or other elements, and across or along a UV light source. The flow direction can vary here. Alternatively or additionally, the polarity of the electric field can be static or change cyclically or acyclically. As an alternative to the constant field, an alternating field can also be used. The UV light source works in the wavelength range between 190 and 280 nanometers, preferably in the wavelength range between 220 and 260 nanometers. Here, UV light with a discrete wavelength and/or UV light with a wavelength spectrum of different wavelengths is used. The air cleaning housing is designed accordingly in order to sterilize the air flowing through it by means of UV radiation and by means of a high-voltage electric field.

The air cleaner housing is advantageously tailored to the application here and, compared to other known technologies, allows an extremely flat design of between 20 mm and 50 mm, preferably between 30 mm and 40 mm, overall height.

It is also provided that individual inner surfaces and/or outer surfaces of the air cleaner housing are contacted at least in regions or have an electrically conductive coating or conductor tracks.

Advantageously, room air can be circulated, sucking in from one direction and ejecting in the opposite direction. Furthermore, it can be influenced that the circulation takes place in such a way that the largest possible spatial area is circulated and not just a small area located directly in the vicinity of the air cleaning arrangement.

As shown, the air cleaning arrangement according to the invention can be used, not exclusively, in medical care areas and premises, in schools, in offices, in meeting rooms or at meeting tables, in areas frequented by the public and also in the private sphere.

Further advantageous configurations of the invention are presented in the dependent claims.

By the at least one air cleaner housing being pushed, inserted or integrated into at least one air duct or air duct section and/or the air duct forming at least one air cleaner housing wall of the air cleaner housing and/or the air cleaner housings being electrically connected to one another in the case of two or more air cleaner housings, a achieved simple and compact design and a simple construction. In addition, the flexibility in the application or for the application is increased and the field of application is enlarged.

The air cleaner housing can be electrically connected to one another directly or indirectly via at least one further component or assembly, such as a controller or wiring or a printed circuit board with wiring.

The assembly and the internal structure are simplified by the fact that the air cleaner housings are electrically connected to one another directly or indirectly or to other components alone or in an air duct by means of plug connectors. In addition, errors during assembly can at least be minimized or avoided.

Since the at least one UV light source is strip-shaped or angled or curved as at least one UV light source arrangement and is arranged transversely, at an angle, curved and/or parallel to the flow direction of the air and/or opposite one another, the flowing air or the air flow becomes reliable reached by UV light.

Advantageously, at least one of the inner surfaces of the air cleaner housing is at least partially light-reflecting or has a light-reflecting coating, which promotes the propagation of the UV light in the air cleaner housing.

The at least one UV light source advantageously extends as at least one UV light source arrangement, for example or preferably in the form of strips or in an angled or curved manner, over the width of the air cleaner housing. Alternatively, several strip-shaped UV light sources can also be arranged next to one another or overlapping, over which or along which the air flows.

In the case of a round air cleaner housing, the UV light source can be designed as at least one UV light source arrangement, for example as a circular ring or in the form of circulating waves or in a zigzag form or as radial rays. In a round air cleaner housing, the air can flow radially, tangentially, axially and/or circumferentially with radial or tangential or axial flow areas or in another variation or combination of flow directions through the air cleaner housing.

The at least one UV light source, for example or preferably in the form of a strip, is advantageously aligned with its main emission direction in at least two, preferably opposite, directions in order to avoid shadowing. Depending on the orientation, one UV light source or several UV light sources can be used for this. For example, radiation of the UV light towards one another or back to back away from one another or other radiation of the UV light can also be considered.

In a further development, the air cleaner housing walls have conductor tracks or other conductive structures or coatings on the outer surface and/or inner surface, so that contacts can be made for the respective air cleaner housing or peripherally for other air cleaner housings or other components or assemblies, or components can be electrically connected more easily or that functionalities or components can be mapped directly. For example, capacitances, inductances and resistances as well as electrode surfaces can be mapped directly over conductor structures.

Since a high-voltage generator is present for generating the high voltage, with the high-voltage generator being electrically connected to at least two electrode surfaces, the structural design and at the same time the electrical design are simplified.

Advantageously, the electrode surfaces are formed on at least partially electrically conductive and/or structured or structured electrically conductive inner surfaces of two opposing air cleaner housing walls of the air cleaner housing, with the opposing air cleaner housing walls being arranged parallel or lengthwise to the flow direction of the air, which promotes a compact design and additional components or components can be omitted.

Two electrode pads of different polarity or different potential can form a pair of electrode pads.

In a further development, the electrode surfaces are arranged on at least partially electrically conductive and/or structured electrode plates in the air cleaner housing, the electrode plates being arranged at a distance transversely and/or longitudinally and/or obliquely to the flow direction of the air.

The electrode plates are advantageously arranged with the electrode surfaces parallel to one another.

The electrode plates with the electrode surfaces can be arranged, for example, as a stack which the air can flow around and/or through transversely or lengthwise or diagonally.

In particular with more than two electrode plates, for example as a stack, which the air can flow around and/or through in the direction of flow transversely or lengthwise or diagonally, the polarity or the potential of the electric field on the electrode plate(s) or electrode surfaces is different in the direction of flow or alternately.

Advantageously, an electrode plate, which for example cannot be a metal plate, a conductive plastic plate or a conductively coated plastic plate or a double-sided printed circuit board, has the same potential or the same polarity on both surfaces or sides. For this purpose, the double-sided printed circuit board can be plated through.

Recesses or passage openings can advantageously be present in the electrode plates, so that the air flow and air distribution as well as the effect of the electrical field are promoted.

In addition, the effect of the UV light can be promoted with the recesses or passage openings and with the structured electrode plates.

The recesses or through-openings can have projections that are also formed when the recesses or through-openings are produced, for example. Thus, the projections can surround the recesses or through-openings over the respective circumference partially or in sections or circumferentially. Alternatively or additionally, it can be arranged or provided on or around the recesses or through-openings or as pieces of pipe or tubular overhangs. For example, the pipe pieces or tubular projections can be glued, welded, soldered, printed and/or provided as an integral part as a separate part. Likewise, the pieces of pipe or tubular projections can be inserted or pushed through the through-openings.

These pieces of pipe or tubular projections can be provided on one side or both sides on or around the recesses or passage openings. A combination of the pipe sections or tubular overhangs with the projections is also possible.

Any or different or individual cross-sections, lengths and designs of the respective axial ends of the pipe sections or tubular overhangs or projections can be considered here.

Furthermore, the distances between the recesses or through-openings can also be selected individually or differently. The pipe pieces or tubular projections with the projections on or around the recesses or through-openings can touch one another or be in contact with one another.

Alternatively or additionally, thorn-like, cylindrical, rod-like, conical or pyramid-like or needle-like projections or elevations can be considered as structures for the structured electrode plates. These, for example, thorn-like, cylindrical, rod-shaped, conical or pyramid-shaped or needle-shaped protrusions or elevations promote the effect of the electric field. In addition, areas with a higher field strength are formed, which favors the influence of the electric field on the air or the air flow. These, for example, thorn-like, cylindrical, rod-shaped, conical or pyramid-shaped or needle-shaped protrusions or elevations can have spherical ends.

The, for example, thorn-like, cylindrical, rod-shaped, conical or pyramid-shaped or needle-shaped projections or elevations are preferably arranged in the area between the recesses or through-openings on or as part of the electrode plate.

Furthermore, the for example thorn-like, cylindrical, rod-shaped, conical or pyramid-shaped or needle-shaped protrusions or elevations can be arranged on one side or both sides of the electrode plate.

For example, the thorn-like, cylindrical, rod-shaped, conical or pyramid-shaped or needle-shaped protrusions or elevations can be provided with the formation or manufacture of the through-opening or can emerge from the through-opening, which can be produced in the same or a subsequent operation from the through-opening or from the plane of the electrode plates be bent out.

In a development of the invention, the electrode plates or electrode surfaces of one polarity or one potential of the electric field or every second electrode plate have a non-conductive or an insulating coating. Preferably, in the arrangement of the electrode plates as a stack or in the respective flow direction of the air, the first and each white The other odd-numbered electrode plate has an insulating or non-conductive coating. Likewise, in the arrangement of the electrode plates, each even-numbered electrode plate may have an insulating or non-conductive coating. This coating can be, for example, a paint, a silicone coating or another suitable coating. Likewise, the insulating or non-conductive coating can also be an appropriate surface modification or surface finish.

The insulating or non-conductive coating ensures that a charge equalization of charged or ionized, for example, particles or viruses, microscopically small creatures and bacteria is prevented or delayed, but the electrostatic forces act for attraction.

Preferably, the first downstream electrode plate or surface has one polarity or potential and each other of the electrode plates or surfaces of that polarity or potential has the non-conductive or an insulating coating or coating, while the second electrode plate or surface has the different or alternating polarity or potential and each other of the electrode plates or electrode surfaces with that or that different or alternating polarity or potential does not have a non-conductive or an insulating coating. In this way, a charge equalization of charged or ionized particles or viruses, microscopic creatures and bacteria can be avoided or delayed and the residence time and thus the influence of the UV light can be increased.

Advantageously, the recesses or through-openings in the electrode plates can be arranged in alignment with one another and/or offset from one another, so that turbulence reduces air distribution or the formation of areas of still air in which, for example, particles or viruses, microscopic organisms and bacteria can be influenced by electrical Field reach and are held by the electric field and / or the still air, so that the exposure time of the UV light is increased and thus in particular under the action of the UV light and / or the electric field, the inactivation or killing, for example, of the particles or viruses , microscopic creatures and bacteria are further favored.

In a further development, the electrode surfaces are formed on at least partially electrically conductive and/or structured inner surfaces of a circumferential air cleaner housing wall of the air cleaner housing and on at least one electrode profile arranged concentrically or centered or distributed. The at least one electrode profile arranged concentrically or in a centered or distributed manner and the surrounding air cleaner housing wall are arranged approximately parallel or lengthwise to the flow direction of the air.

As a result, the electric field existing between the electrode surfaces extends along the flow direction of the air in the air cleaner housing.

Any desired cross-sections for the electrode profiles and the air-cleaning housing wall can advantageously be considered.

Advantageously, the at least one electrode profile arranged concentrically or centered or distributed is designed to correspond to the circumferential air cleaner housing wall. This can promote the formation and the effect of the electric field.

Because the at least one electrode profile does not correspond to the surrounding wall of the air cleaner housing, an electric field with individual properties, propagations and field strengths can be generated.

Advantageously, the surfaces of the at least one electrode profile arranged concentrically or centered or distributed and/or the air cleaning housing wall have surface structures, whereby the formation and the effect of the electrical field and the air distribution is promoted.

Advantageously, two or more electrode profiles are arranged concentrically spaced apart, with the polarity or the potential of the electric field being different or alternating with the electrode surface of the adjacent electrode profile or with the air cleaner housing wall. The air can flow through the remaining spaces and the electric field can achieve its effect.

At least one electrode profile is advantageously arranged centered on the air cleaner housing wall, so that the electric field is formed uniformly between the respective electrode surfaces and the air is guided through it.

By distributing two or more electrode profiles, the polarity or the potential of the electric field can be set differently or alternately to the electrode surface of the adjacent electrode profile or to the air cleaner housing wall.

The electrically conductive and/or structured or structured electrically conductive inner surfaces include individual shapes or layouts or surface structures of the conductive structures or coatings of the relevant inner surfaces or electrode surfaces. The electrically conductive and/or electrically structured inner surfaces or electrode surfaces also include recesses or holes in the conductive structures or electrode surfaces or coatings or through-holes which reach through the conductive structures or electrode surfaces or coatings and a double-sided printed circuit board. This results in a plated through hole.

The recesses or holes or through-holes can have different cross-sections and/or sizes. Likewise, the recesses or holes or through-holes can be distributed evenly or randomly. The cross-sections and/or sizes as well as the distribution can vary according to need.

Depending on the application, in the case of conductive structures or coatings on both sides, depending on the application, the conductive structures or coatings on both sides can be through-contacted through the through-holes.

Since a double-sided printed circuit board is arranged at least in regions between and at a distance from the opposing air cleaner housing walls with the electrode surfaces, the compact design is promoted, since the interior space is used extensively. As an alternative to a double-sided printed circuit board, other suitable circuit carriers or carrier structures that implement or enable the same function can also be used.

In a development, the double-sided printed circuit board has at least one additional electrode surface and/or conductor structure on both sides, with at least one additional electrode surface being electrically connected to the high-voltage generator on both sides, thereby improving the cleaning effect or disinfection effect to be achieved.

By arranging the at least one UV light source or at least one UV light source arrangement on the double-sided printed circuit board and/or on at least one or on one of the opposite air cleaning housing walls, the cleaning effect or disinfection effect to be achieved is improved.

By arranging the high-voltage generator in the air cleaner housing or outside of the air cleaner housing or in the air duct, a compact design of the air cleaner housing is favored.

By having at least one lamella and/or at least one flow opening in the lateral air cleaner housing walls arranged at least approximately transversely to the flow direction of the air, the UV light is prevented from escaping and protection against accidental contact is promoted.

Advantageously, the lamellae are aligned parallel to one another and spaced apart. Lamellae which are aligned in parallel are also understood to be circular or arc-shaped and lying one above the other or offset one above the other in mutually parallel planes. Thus, circular or arcuately curved lamellae, each with the same radius or the same curvature, which are arranged wall-like spaced one above the other about a center point and form a lateral surface or are arranged in the shape of a cylinder jacket, are understood to be parallel to one another.

The at least one flow opening can advantageously be arranged as a hole pattern in the lateral air cleaner housing wall, with the lateral air cleaner housing wall being formed from at least two spaced air cleaner housing wall planes and the air cleaner housing wall planes each having the at least one flow opening as a hole pattern.

All arrangements of openings with any desired cross-section that can be arranged in the lateral air cleaner housing wall or in the air cleaner housing wall planes are understood as a hole pattern. Round and/or angular openings and/or slits or other cross sections can be considered.

Advantageously, the flow openings are offset from one another as a hole pattern of the at least two spaced air cleaner housing wall planes, so that no UV light escapes from the air cleaner housing.

By the cross-section of the slats being roof-shaped or V-shaped or A-shaped or having at least a half-wave, with the tapered area or the crest or the trough of a slat overlapping the wide end or the downwardly or upwardly open swell of the adjacent slat protrudes, it is favored that no UV light escapes from the air cleaner housing and at the same time the pressure loss or air resistance is low.

By the slats or at least one of the lateral air cleaner housing walls or at least If at least one of the air cleaner housing wall planes has a non-reflective surface, it is favored that no UV light escapes from the air cleaner housing, not even via reflection.

In a further development, there is a controller for the at least one UV light source and/or the at least one electric field and/or the at least one blower and/or the flat light source, so that automated operation based on requirements is made possible.

The controller is advantageously electrically connected at least to the UV light source and/or the high-voltage generator and/or the at least one blower.

Since at least one sensor is present and at least connected to the controller, the operation can be influenced and/or controlled as a function of different environmental parameters. A wide variety of sensors come into consideration, which adapt the function and operation to the most diverse needs and necessities. These can be, for example and not exclusively, a motion sensor and/or at least one proximity sensor and/or at least one particle sensor and/or at least one multisensor at least for detecting organic and/or inorganic particles and/or a gas sensor. Static operation of the lighting or the fan, or operation triggered directly by a sensor, is also provided.

In a development, the controller has at least one wireless communication interface, which means that different, preferably mobile, end devices can be operated, configured, or controlled.

By providing the controller with at least one user administration or user IDs or user profiles or user-dependent setting profiles in the controller, preferred settings can be set user-dependently.

It is thus possible, when a user is in the receiving range of the wireless communication interface, for the controller to set the at least one UV light source and/or the at least one electric field and/or the at least one blower based on a user profile or user-dependent setting profile will.

A prioritization is provided here, which takes into account different users in the reception area of the wireless communication interface and gives them corresponding preference.

Since the fastening device is also an electric power supply line, a separate supply line can be dispensed with and the structure can be simplified and material can be saved.

However, other or separate electrical power supply lines are also included and can also be provided depending on the design.

The fastening device is routed into the at least one air cleaner housing as an electric power supply line and is fixed and electrically connected to or in or with the electrically conductive and/or structured inner surface of at least one of the opposing air cleaner housing walls and/or on or in or with the double-sided printed circuit board of the at least one air cleaner housing is, the construction and the electrical connection of the lighting device and the at least one air cleaner housing itself and also simplified against a faulty connection.

Wiring or contacting is simplified in that the housing wall opposite the housing wall with conductor tracks or other conductive structures on the outer surface and/or inner surface has conductor tracks or other conductive structures on the outer surface and/or inner surface. Additional faulty wiring can be avoided in this way.

Since the air cleaner housing walls have the electrode surfaces with conductor tracks on the outer surface and/or inner surface or other conductive structures on the inner surfaces, the structure and also wiring or contacting of the air cleaner housing are simplified.

In one development, there are baffles on or in the air cleaner housing and/or in the air duct and/or on the at least one air inlet opening and/or on the air outlet opening or on the fan to direct or influence or improve the air flow.

In one development, a seal is provided between the at least one air cleaner housing and the air duct. This favors the air flowing only or at least predominantly through the at least one air cleaner housing.

• 1a und 1b die Schnittdarstellung einer Luftreinigungsanordnung aus unterschiedlichen Blickrichtungen,
• 2a und 2b die Schnittdarstellung einer Luftreinigungsanordnung in einem Luftkanalgehäuse aus unterschiedlichen Blickrichtungen ,
• 3 die Schnittdarstellung einer Luftreinigungsanordnung als Anordnung von zwei miteinander verbundenen Luftreinigungsgehäusen,
• 4 ein geöffnetes Luftreinigungsgehäuse mit integrierten Gebläsen einer Luftreinigungsanordnung in räumlicher Ansicht von oben,
• 5 und die 6 die seitliche Schnittdarstellung des Luftreinigungsgehäuse der Luftreinigungsanordnung der 4,
• 7 ein geöffnetes Luftreinigungsgehäuse mit integrierten Gebläsen einer Luftreinigungsanordnung in räumlicher Ansicht von oben,
• 8 und die 9 die seitliche Schnittdarstellung des Luftreinigungsgehäuse der Luftreinigungsanordnung der 7,
• 10 die seitliche Schnittdarstellung einer runden Luftreinigungsanordnung,
• 11 die seitliche Schnittdarstellung einer runden Luftreinigungsanordnung in einem Luftkanalgehäuse,
• 12 die Schnittdarstellung eines Details der 12,
• 13 die schematische Darstellung einer Anordnung von Elektrodenplatten,
• 14 die Schnittdarstellung eines Details der 12,
• 15 die seitliche Schnittdarstellung einer runden Luftreinigungsanordnung,
• 16 die Schnittdarstellung eines Details der 15,
• 17 eine geöffnetes Luftreinigungsgehäuse mit integrierten Gebläsen einer Luftreinigungsanordnung in räumlicher Ansicht von oben und
• 18 bis 22 Elektrodenplatten in unterschiedlichen Ansichten.

Several exemplary embodiments of the invention are illustrated in the drawings and are described in more detail below. Show it:

• 1a and 1b the sectional view of an air cleaning arrangement from different perspectives,
• 2a and 2 B the sectional view of an air cleaning arrangement in an air duct housing from different perspectives,
• 3 the sectional view of an air cleaning arrangement as an arrangement of two interconnected air cleaning housings,
• 4 an open air cleaning housing with integrated fans of an air cleaning arrangement in a spatial view from above,
• 5 and the 6 the side sectional view of the air cleaner housing of the air cleaner assembly 4 ,
• 7 an open air cleaning housing with integrated fans of an air cleaning arrangement in a spatial view from above,
• 8th and the 9 the side sectional view of the air cleaner housing of the air cleaner assembly 7 ,
• 10 the side sectional view of a round air cleaning arrangement,
• 11 the side sectional view of a round air cleaning arrangement in an air duct housing,
• 12 the sectional view of a detail of the 12 ,
• 13 the schematic representation of an arrangement of electrode plates,
• 14 the sectional view of a detail of the 12 ,
• 15 the side sectional view of a round air cleaning arrangement,
• 16 the sectional view of a detail of the 15 ,
• 17 an open air cleaning housing with integrated fans of an air cleaning arrangement in a spatial view from above and
• 18 until 22 Electrode plates in different views.

The air cleaning arrangement 7 according to the invention 1a and 1b as a first exemplary embodiment comprises at least one, for example cuboid, air cleaner housing 7a. At least one air inlet opening 4 and at least one air outlet opening 5 are present in the at least one air cleaning housing 7a. Furthermore, at least one UV light source 8 is arranged in the at least one air cleaning housing 7a and at least one electrical field 9 generated by means of high voltage is present. The at least one air inlet opening 4 is arranged in the at least one air cleaner housing 7a in such a way that air flows through the at least one air inlet opening 4 into the at least one air cleaner housing 7a and the air flows out of the at least one air cleaner housing 7a through the at least one air outlet opening 5.

The at least one UV light source 8 is arranged in the air cleaning housing 7a in such a way that the air flow reaches or flows around the UV light source 8 at least in certain areas or that the UV light from the UV light source 8 reaches the flowing air at least partially, preferably comprehensively, and the UV light achieves a corresponding effect against the viruses, microscopic creatures and bacteria found in the room air. Likewise, the at least one electric field 9 is arranged in the air cleaner housing 7a in such a way that the air flowing into or through the air cleaner housing 7a flows at least partially, preferably comprehensively, through the electric field 9 or is detected by the electric field 9 and the electric field 9 through the high voltage achieves a corresponding effect against the viruses, microscopic creatures and bacteria found in the room air.

Although conceptually an assignment of air inlet opening 4 or air outlet opening 5 was made in the exemplary embodiments, it is also included that the air inlet opening 4 and air outlet opening 5 are replaced by a flow reversal without making a change to the described construction or the described structure. However, this may still be necessary if absolutely necessary. In this respect, the air inlet opening 4 and air outlet opening 5 were specifically assigned in particular only for an exemplary representation serving for better understanding.

In the air cleaner housing 7a there are also electrode surfaces 12 parallel to the flow direction 2 of the air, one electrode surface 12 being formed on each electrically conductive and/or structured inner surface of two opposite air cleaner housing walls 7b of the air cleaner housing 7a. Two further electrode surfaces 12 and conductor structures 14 are arranged on both sides on a double-sided printed circuit board 13 arranged between and at a distance from the opposite air cleaner housing walls 7b with the electrode surfaces 12 . Here, the electrode surfaces 12 of the two opposing air cleaner housing walls 7b are interconnected and each have the same potential, while the two-sided electrode surfaces 12 on the double-sided printed circuit board 13 are also interconnected and have an opposite potential to the electrode surfaces 12 of the two opposite air cleaner housing walls 7b.

Advantageously, the electrode surfaces 12 on both sides are congruent and through-contacted on the double-sided printed circuit board 13 . Likewise, the conductor structures 14 can be present on both sides and connected to one another, if present and depending on requirements.

In addition, plated-through recesses or holes can be present in the double-sided printed circuit board 13 in the area of the electrode surfaces 12, on the one hand to establish an electrical connection between the two sides of the double-sided printed circuit board 13 or between the electrode surfaces 12 of the same polarity and on the other hand to promote air turbulence.

Thus, two electrode surface pairs are formed by the electrode surfaces 12 of the two opposite air cleaner housing walls 7b and the electrode surfaces 12 on the double-sided printed circuit board 13, so that in each case between one of the electrode surfaces 12 of one of the two opposite air cleaner housing walls 7b and the electrode surface 12 on the double-sided printed circuit board facing this 13 an electric field 9 is generated by means of high voltage.

A high-voltage generator 11 is present in the air cleaner housing 7a for generating the high voltage. If a controller 16 is present, the high-voltage generator 11 is connected to it.

A separate power pack or an existing power supply, for example that of a vehicle, can serve as the power supply.

Furthermore, at least one UV light source 8 is present in the air cleaner housing 7a in the form of at least one UV light source arrangement 8a in the form of a strip across the width of the air cleaner housing 7a transversely to the flow direction 2 of the air. In the specific example, the respective UV light source arrangement 8a is arranged on both sides of the double-sided printed circuit board 13 and radiates in the direction of the two opposite air cleaning housing walls 7b. In an alternative embodiment, the UV light source arrangement 8a can also be arranged on the two opposite air cleaner housing walls 7b and aligned to the center or to the double-sided circuit board 13.

The air cleaner housings 7a each have fins 15 in the lateral air cleaner housing walls 7c of the air cleaner housing 7a arranged transversely to the flow direction 2 of the air. The slats 15 are each aligned parallel to one another and spaced apart. The cross-section of the slats 15 is V-shaped, with the tapered portion of one slat 15 overlapping the wide end of the adjacent slat.

Plug connectors 20 are provided for making contact or for connecting the air cleaner housing 7a to the periphery, such as a controller 16, an electrical power supply line 18 or for an electrical power distribution system, as well as to other air cleaner housings 7a.

A fan (not shown) can be arranged outside the air cleaning housing 7a in this example or is already present for a ventilation application, for example.

In the 2a and 2 B an air cleaner housing 7a is shown in an air duct housing 1 from different perspectives. In addition to or deviating from 1a and 1b the air cleaner housing 7a is arranged or surrounded in an air duct housing 1 . In addition, the air cleaner housing 7a is sealed off from the air duct housing 1 with a seal 22 . The air duct housing 1 has an air duct 3 in which the air cleaner housing 7a is arranged, in which air flows and flows through the air inlet opening 4 into the air cleaner housing 7a and through the air outlet opening 5 out of the air cleaner housing 7a into the air duct 3.

In addition to the structure already described with the electrode surfaces 12 on the two opposite air cleaner housing walls 7b and the electrode surfaces 12 on the double-sided printed circuit board 13, whereby two pairs of electrode surfaces are formed, it is shown that the same potential, for example ground or the negative pole of the high-voltage generator, is present on the electrode surfaces 12 of the two opposing air cleaner housing walls 7b and the opposite potential, for example the positive pole or high-voltage pole or high-voltage output of the high-voltage generator is applied to the electrode surfaces 12 on the double-sided circuit board 13.

The air cleaner housing 7a has contact openings 19 on one, preferably the upper, of the two opposing air cleaner housing walls 7b with the electrically conductive and/or structured inner surface with conductor tracks or other conductive structures or coatings. Likewise, in the concrete example above existing double-sided circuit board 13 each contact openings 19 available. These respective contact openings 19 are congruent with each other and, for example, with a contact rod 21 for an electric power supply line 18 and with openings 27 provided for this purpose in the upper wall 26 of the air duct housing 1, so that the respective contact rod 21 extends up to the contact openings 19 in the respective air cleaner housing wall 7b and which, depending on the polarity, also extends to the double-sided printed circuit board 13 in the respective air cleaner housing 7a.

Depending on the specific configuration, the contact openings 19 can therefore also have a connection to the electrically conductive and/or structured inner surfaces with conductor tracks or other conductive structures or coatings and/or to the conductor structure 14 .

Like in the 2 B shown, one of the contact rods 21 for the electric power supply line 18 reaches, for example, up to the contact opening 19 in the double-sided printed circuit board 13, while another of the contact rods 21 for the electric power supply line 18 only reaches the contact opening 19 of the electrically conductive and/or structured inner surface of the upper air cleaning housing wall 7b is enough.

The unused contact openings 19 are closed with a blind plug 23, for example by means of grub screws.

Via the electrically conductive and/or structured inner surface with conductor tracks or other conductive structures or coatings of the air cleaning housing walls 7b and the conductor structure 14 of the double-sided printed circuit board 13, the electrical energy is distributed to the controller 16, if present, to the blower 6, if present, and to the respective, if necessary existing other air cleaner housing 7a, since the supply voltage is routed via at least one of the contact rods 21 as an electrical energy supply line 18 and at least one other of the contact rods 21 is routed as an electrical energy supply line 18 to ground or the reference potential. If necessary, control signals are also to be distributed between the controller 16 that may be present and the air cleaning housings 7a that may be present in multiple numbers and the fan 6 that may be present, via appropriate contacting or wiring. Sensors 17 that may be present can also be electrically connected to at least controller 16 that may be present, or directly to an illuminant that may be present, or to fan 6 that may be present.

In this example, a blower (not shown) can be arranged outside the air cleaning housing 7a in an air duct housing 1 or is already present for a ventilation application, for example.

If fastening devices are present, they can also be used as an electrical power supply line 18 or can be combined with the electrical power supply line 18 .

In 3 are two air cleaning arrangements 7, each with an air cleaning housing 7a, as already mentioned above 1a and 1b describe, arranged.

A controller 16 is arranged between the two air cleaner housings 7a. The direction of flow 2 of the air is in each case directed through the air inlet openings 4 arranged laterally on the outside, through the air cleaning housing 7a and through air outlet openings 5 .

When the flow is reversed, for example by a fan 6 rotating in the opposite direction, the air flows in the opposite direction through the air cleaning housing 7a, so that in this case the air inlet openings 4 are interchanged with the air outlet openings 5 .

A cascade of air cleaner housings 7a is also possible, so that the air flows through two or more air cleaner housings 7a one after the other.

The controller 16 is thus flushed with the air and at the same time cooled, regardless of the direction of flow 2 of the air.

The air cleaning housing 7a can be electrically connected to the controller 16, if present, via plug connectors (not shown). Likewise, a blower 6 that may be present can be electrically connected to an air cleaner housing 7a via plug connectors 20 and via the electrically conductive and/or structured inner surface with conductor tracks or other conductive structures or coatings of at least one of the two opposite air cleaner housing walls 7b to the controller 16 that may be present.

If there is no controller 16, the air cleaning housings 7a can be electrically connected to one another and/or to fans 6 that may be present.

Alternatively (not shown), the air cleaning arrangement 7 has no control and operates in a static mode. For this are the nor the air cleaner cases 7a are electrically connected to each other via wirings.

In an alternative embodiment (not shown), there is no double-sided printed circuit board 13 in the air cleaner housing 7a between the two opposing air cleaner housing walls 7b. The UV light source 8 as at least one UV light source arrangement 8a is then arranged on the two opposing air cleaning housing walls 7b. The electrode surface 12 is also arranged in each case on the two opposite air cleaner housing walls 7b.

For efficient operation, there are, for example, different sensors 17 such as a movement sensor and a multi-sensor at least for detecting organic and/or inorganic particles and a gas sensor, each of which can be connected to the controller 16 that may be present or, if no controller 16 is present, directly to a possibly existing fan 6 are connected. The sensors 17 are preferably also arranged in the flow area of the air and thus detect the requirement based on the air sucked in.

Another embodiment of the air cleaning arrangements 7 according to the invention is in the 4 until 6 shown. Here, the air inlet openings 4 and the air outlet openings 5 are located on opposite outer edges or on opposite lateral outer surfaces of the air cleaner housing 7a.

In the illustration of the air cleaning arrangements 7 in 4 12, the top of the air cleaner housing walls 7b of the air cleaner housing 7a is removed and shown with the electrode surface 12 for the electric field 9 only in outline. In the specific example, the air cleaner housing 7a has two fans 6, a controller 16 between the fans 6 and on two opposite air cleaner housing walls 7b, which are arranged parallel to the direction of flow 2 of the air, there are areas of electrically conductive and/or structured inner surfaces on which the electrode surfaces 12 for the electrical Field 9 are formed. Furthermore, the high-voltage generator 11 is arranged in the air cleaner housing 7a and a UV light source 8 is arranged on each of the two opposite air cleaner housing walls 7b, which are arranged parallel to the flow direction 2 of the air, as at least one UV light source arrangement 8a, which are arranged in strips and transversely to the flow direction 2 of the air. Flow openings 31 as air inlet openings 4 and air outlet openings 5 are present in the lateral air cleaning housing walls 7c arranged transversely to the flow direction 2 of the air. The air from the fans 6 flows directly to and through the air outlet openings 5.

In the 5 and 6 each shows the lateral sectional view of an air cleaning arrangement 7 with an air cleaning housing 7a. The air flows from outside the air cleaner housing 7a via the air inlet openings 4 through the air cleaner housing 7a, through the fans 6 further via the air outlet openings 5 to the outside of the air cleaner housing 7a. Depending on the conveying direction of the fan 6, a flow reversal or opposite flow direction is also possible in this example, in which case the air inlet openings 4 and the air outlet openings 5 would then also be correspondingly interchanged. In this respect, the assignment made here is to be regarded as an example of a specific direction of flow 2 .

As further supplemented in 5 and 6 is shown, the electrode surfaces 12 for the electric field 9 are present in the air cleaner housing 7a parallel to the direction of flow 2, with one electrode surface 12 each being arranged on an electrically conductive and/or structured inner surface of two opposite air cleaner housing walls 7b of the air cleaner housing 7a and connected to the high-voltage generator 11 connected is.

In the 5 Electrode surfaces 12 shown for the electric field 9 have different polarities or potentials.

The UV light source 8 as at least one UV light source arrangement 8a is arranged on the two opposite air cleaner housing walls 7b parallel to the direction of flow 2 and aligned with one another.

In 6 two further electrode surfaces 12 are additionally arranged on both sides of a double-sided printed circuit board 13 arranged between and at a distance from the opposing air cleaner housing walls 7b with the electrode surfaces 12.

Here, however, the electrode surfaces 12 of the two opposite air cleaner housing walls 7b are interconnected and each have the same potential, while the two-sided electrode surfaces 12 on the double-sided printed circuit board 13 are also interconnected and have an opposite potential to the electrode surfaces 12 of the two opposite air cleaner housing walls 7b. Furthermore, conductor structures 14 are present on the double-sided circuit board 13 .

The UV light source 8 as at least one UV light source arrangement 8a is arranged on both sides of the double-sided printed circuit board 13 and is aligned with the opposite air cleaning housing walls 7b.

In the 7 until 9 is as a variant of the in the 4 until 6 illustrated embodiment, a power supply trough 25 with power supplies 24 is present, which protrudes from above into the air cleaner housing 7a. For this purpose, the upper air cleaning housing wall 7b is correspondingly cut out for the power pack trough 25 . The electrically conductive and/or structured inner surfaces with conductor tracks or other conductive structures or coatings and the electrode surface 12 are correspondingly reduced.

In 9 a double-sided circuit board 13 is arranged between and spaced from the opposing air cleaner housing walls 7b with the electrode surfaces 12, which circuit board has a further electrode surface 12 and conductor structures 14 on both sides. This double-sided printed circuit board 13 is also recessed and the further electrode surfaces 12 and/or conductor structures 14 present on it are correspondingly reduced in size.

Depending on the depth of the power pack trough 25, the lower air cleaning housing wall 7b is also recessed. Alternatively, at least the electrode surface 12 or the conductive structures have been removed in the area of the power pack trough 25 on the lower air cleaning housing wall 7b.

For the rest of the structure shown in the 7 and 9 can on remarks too 4 until 6 to get expelled.

The controller 16 is connected via plug connectors 20 at least to the opposite air cleaner housing walls 7b with the electrically conductive and/or structured inner surfaces and electrode surfaces 12 and to the double-sided printed circuit board 13 and its conductor structures 14 and electrode surfaces 12.

A third embodiment of the air cleaning arrangement 7 according to the invention is shown in FIG 10 shown as a round air cleaning arrangement 7 .

The air cleaner housing 7a is designed in the shape of a circular ring with a uniform or constant axial extent over the radius. The surfaces of the outer and inner circles are arranged approximately transversely to the flow direction 2 of the air on the side air cleaner housing walls 7c of the air cleaner housing 7a with the air inlet openings 4 and the air outlet openings 5 . In the lateral air cleaner housing walls 7c, as in 10 shown, slats 15 present. The slats 15 are each aligned parallel to one another and spaced apart. Alternatively, flow openings 31 can also be used.

Inside the inner circle or inner circle of the air cleaner case 7a, as shown in FIG 10 shown, the controller 16 and a blower 6 arranged above it. Accordingly, the air can be sucked in radially and blown out axially upwards or sucked in axially from above and blown out radially.

The air cleaning arrangement 7 with at least one UV light source 8 and at least one electrical field 9 generated by means of high voltage is arranged in the air cleaning housing 7a.

A high-voltage generator 11 is provided for generating the high voltage. The high voltage generator 11 is connected to electrode pads 12 .

The electrode surfaces 12 are arranged on the one hand on at least partially electrically conductive and/or structured inner surfaces of two oppositely spaced air cleaner housing walls 7b, which are formed by the axial, i.e. the upper and lower, boundary surfaces of the annular air cleaner housing 7a.

Furthermore, a circular ring-shaped double-sided printed circuit board 13 is arranged at a distance from the electrode surfaces 12 between the spaced-apart opposite air cleaner housing walls 7b, which also has electrode surfaces 12 and also conductor structures 14 .

In this case, the electrode surfaces 12 of the two opposing air cleaner housing walls 7b are also connected together and each have the same potential of the electric field 9, while the two-sided electrode surfaces 12 on the double-sided printed circuit board 13 are also connected together and have an opposite potential of the electric field 9 to the electrode surfaces 12 of the have two opposite air cleaner housing walls 7b.

The UV light source 8 is designed as a circumferential and therefore curved UV light source arrangement 8a and is arranged on the double-sided printed circuit board 13 and aligned with the opposite air cleaning housing walls 7b.

Furthermore, openings 27 for contact rods 21 as an electric power supply line 18 leading to Kon clock openings 19 in the upper of the two opposite ones

Air cleaning housing walls 7b with the electrically conductive and/or structured inner surfaces and also with contact openings 19 in the double-sided printed circuit board 13 present in the specific example are each congruent.

The respective contact rods 21, which are also the electric power supply line 18, extend for an electrical connection to the contact openings 19 in the respective air cleaner housing wall 7b and, depending on the polarity, also to the double-sided printed circuit board 13 in the air cleaner housing 7a and provide an electrical connection.

Depending on the specific configuration, the contact openings 19 have an electrical connection to the electrically conductive and/or structured inner surfaces with conductor tracks or other conductive structures or coatings and/or to the conductor structure 14 .

As shown, for example, one contact rod 21 as an electrical power supply line 18 extends to the contact opening 19 in the double-sided printed circuit board 13, while the other contact rod as an electrical power supply line 18 extends to the contact opening 19 of the electrically conductive and/or structured inner surface of the upper air cleaning housing wall 7b.

A fourth exemplary embodiment of the air cleaning arrangement 7 according to the invention is 11 shown and is elongated in the shape of a cylindrical tube. The air cleaner housing 7a has a fan 6 on each of the axial ends. The air inlet openings 4 and air outlet openings 5 are present axially outside of the fan 6 at the respective opposite axial end.

If present, a controller 16 is arranged in the air cleaner housing 7a. Furthermore, the high-voltage generator 11 is arranged in the air cleaner housing 7a.

At the axial ends in the region of the air inlet openings 4 and air outlet openings 5, the air cleaner housing 7a has a lateral air cleaner housing wall 7c, in which flow openings 31 are arranged as a hole pattern 31a. The lateral air cleaner housing walls 7c are each formed from two spaced air cleaner housing wall planes 7d, the air cleaner housing wall planes 7d each having the flow openings 31 as a hole pattern 31a.

The flow openings 31 as a hole pattern 31a are, as in 14 shown as an example, designed as slots. However, other shapes and cross-sections are not excluded. For example, staggered hole patterns 31a in the form of bores are also possible.

The flow openings 31 as a hole pattern 31a of the two spaced air cleaner housing wall planes 7d of the lateral air cleaner housing walls 7c are each arranged offset to one another. Thus, the flow openings 31 shown as a long dashed line as a hole pattern 31a are those of the one

Air cleaner housing wall plane 7d and the flow openings 31 shown in short dashed lines as a hole pattern 31a that of the other air cleaner housing wall plane 7d. The respective flow openings 31 as a hole pattern 31a are offset on different radii of the air cleaner housing wall planes 7d of the lateral air cleaner housing walls 7c.

In the air cleaner housing 7a, as in 12 shown as a sectional view by way of example, electrode surfaces 12 on at least partially electrically conductive and/or structured electrode plates 32 in the air cleaner housing 7a spaced apart from one another transversely to the direction of flow 2 of the air. The electrode plates 32 each have through openings 34 .

The electrode surfaces 12 are each present on both sides of the electrode plate 32, for example as a printed circuit board with a conductor track on both sides and which are each plated through. The electrode plates 32 alternately have the same polarity or the same potential, so that an electric field 9 is generated or exists between two electrode surfaces 12 of adjacent electrode plates 32 in each case.

An alternative design for electrode plates 32 is in 13 shown. Here, the electrode plates 32 have a star-shaped cross section and are offset or rotated by 15 degrees about the longitudinal axis of the air cleaner housing 7a. The electrode plates 32 also have openings 34 therethrough.

The electrode surfaces 12 are connected to the high-voltage generator 11 accordingly.

Furthermore, a UV light source 8 is arranged as at least one UV light source arrangement 8a in the form of a strip in the air cleaning housing 7a on the surrounding air cleaning housing wall 7b.

Deviating from 11 points is in 15 as a fifth exemplary embodiment of the air cleaning arrangement 7 according to the invention, the air cleaning device Housing 7a has a circumferential air cleaning housing wall 7b, which in some areas includes an electrode surface 12 for a polarity or a potential of the electric field 9. Furthermore, as in 16 shown in section, there are two concentric electrode profiles 33 with electrode surfaces 12, one of the two electrode profiles 33 being arranged concentrically in the other of the two electrode profiles 33. In this case, the inner electrode profile 33 has the same polarity or the same potential of the electric field 9 as the circumferential air cleaner housing wall 7b. The electrode profile 33 has a different potential or a different polarity on the respective electrode surfaces 12 on the inner surface and the outer surface to the electrode surface 12 of the circumferential air cleaner housing wall 7b and to the electrode surfaces 12 of the inner electrode profile 33 . The electrode surfaces 12 are connected to the high-voltage generator 11 accordingly.

In the fourth and fifth exemplary embodiment, electric power supply lines 18 are present (not shown).

Fastening devices can also be present (not shown). At the same time, the fastening devices can form an electric power supply line 18 (not shown).

A fan (not shown) can be provided outside the air cleaner housing 7a or is a fan (not shown) of a peripheral or connected air duct (not shown) or the air duct (not shown) in which the air cleaner housing 7a can be inserted or integrated or coupled .

In addition to round, elongated cross sections, square or triangular or oval or other shapes or cross-sectional shapes or combinations thereof of the flat illuminant 2 and/or the air duct housing 1 can also be considered. Likewise, different cross sections can merge into one another.

The controllable components are advantageously connected to the controller 16, if present. The UV light source 8 and/or the at least one electric field 9 and/or the at least one blower 6 and/or a lamp come into consideration as controllable components.

The embodiments can advantageously have sensors (not shown) for adapting the function and operation to a wide variety of needs and requirements.

The embodiments can advantageously have at least one wireless communication interface and/or a user administration, which makes operation easier for each user and can store default settings.

Another embodiment of the air cleaning arrangement 7 according to the invention 17 includes a cuboid air cleaner housing 7a, for example. In the air cleaner housing 7a, there is an air inlet opening 4 on the underside and an air outlet opening 5 on a lateral outer surface. Furthermore, in the air cleaning housing 7a, eight UV light sources 8 are arranged in strips across the width of the air cleaning housing 7a in opposite pairs transverse to the flow direction 2 of the air.

Furthermore, in the specific example, five electrically conductive and/or structured electrode plates 32 are arranged in the air cleaning housing 7a transversely to the flow direction 2 of the air. The electrode surfaces 12 are arranged on the electrode plates 32 . The UV light sources 8 arranged in pairs opposite one another transversely to the flow direction 2 of the air are each arranged in the area between the respective electrode plates 32 on a printed circuit board 13 and particularly illuminate the area between the electrode plates 32 . The electrode plates 32 are likewise connected to the printed circuit board 13 or arranged on or on the printed circuit board 13 in a conductive manner with the latter. The electrode plates 32 have an alternating polarity or alternately a different potential in the flow direction 2 of the air. The electrode plates 32 are made of metal or have an electrically conductive coating. An electric field 9 generated by means of high voltage is present on the electrode plates 32 with the electrode surfaces 12 . The high-voltage generator 11 required to generate the high voltage is also arranged in the air cleaner housing 7a.

All electrode plates 32 preferably have through openings 34 . The through-openings 34 of the respective electrode plates 32 are arranged in alignment with one another in relation to the through-openings 34 of the adjacent or all of the electrode plates 32 . In a stack formed from electrode plates 32, all through-openings 34 are congruent or aligned.

The first and last electrode plate 32 or the outer electrode plate 32 in each case in the direction of flow 2 of the air has a tubular section 36 or a tubular projection 36 on the side or surface facing the respective adjacent electrode plate 32 in, on or around the through-openings 34 . This can be put on from the Electrode plate 32 be worked out or be made integral with the electrode plate 32 .

The second and fourth electrode plates 32 in each case in flow direction 2 of the air, or the electrode plate 32 adjacent to the outer electrode plate 32 inwards or in the middle, each have spike-like or rod-shaped projections 35 or elevation 35 on both sides or surfaces in the area between the through-openings 34, which each point in the direction of the adjacent electrode plate 32 or are aligned.

The electrode plate 32, which is arranged in the middle or adjacent in the flow direction 2 of the air between the second and fourth electrode plates 32, has a piece of pipe 36 or a tubular projection 36 on both sides or surfaces in, on or around the through-openings 34 . This can likewise be inserted, attached, machined out of the electrode plate 32 or made integral with the electrode plate 32 .

In the respective flow direction 2 of the air before and after the arrangement of the electrode plates 32 and the UV light sources 8, lamellas 15 are arranged, which protect the area of the electrode plates 32 and the UV light sources 8 from contact and light emission. The slats 15 are each aligned parallel to one another and spaced apart. The cross section of the lamellae 15 has a half-wave as the crest. The respective wave crest of a lamella 15 protrudes into the wave crest, which is open at the bottom.

A blower 6 in the form of a radial fan is arranged in the lower air cleaning housing wall 7b at the air inlet opening 4, which draws in air from below and conveys it radially through the fins 15, so that the air flows through the area of the electrode plates 32 and the UV light sources 8 and the air flows out of the air cleaner housing 7a through the air outlet opening 5.

Preferably, the electrode plate 32, which has a piece of pipe 36 or a tubular projection 36 on at least one of the two sides or surfaces and/or on both sides or surfaces in, on or around the through-openings 34, has an insulating covering or an insulating coating Mistake.

The electrode plates 32 are structured and arranged in the air cleaning housing 7a and the UV light sources 8 are arranged in such a way that the dwell time of the particles or viruses, microscopic organisms and bacteria in the area of the electrode plates 32 and the UV light source 8 is increased in order to have a corresponding effect against the viruses, microscopic creatures and bacteria found in the room air.

the 18 until 22 12 show different electrode plates 32 in different top, side and spatial views. The electrode plates 32 each have through openings 34 . In an arrangement of a plurality of electrode plates 32, the through-openings 34 are congruent or aligned in each case with respect to the adjacent electrode plates 32 or a stack of electrode plates 32.

In, on or around the through openings 34 of the electrode plate 32 in 18 a piece of pipe 36 or a tubular projection 36 is arranged on one side or surface.

In, on or around the through openings 34 of the electrode plate 32 in 19 a piece of pipe 36 or a tubular projection 36 is arranged, which projects on both sides or surfaces.

The electrode plate 32 in 20 has thorn-like or conical projections 35 or elevation 35 on both sides or surfaces in the area between the through-openings 34, which are perpendicular or at right angles to the respective surface on both sides or surfaces, are arranged or aligned.

the 21 and 22 show examples of how the, for example, mandrel-like, cylindrical, rod-shaped, conical or pyramid-shaped or needle-shaped protrusions 35 or elevations 35 or the pipe sections 36 or tubular protrusions 36 are already formed or provided as projections 36 when the recesses 34 or through-openings 34 are produced.

For example, as in 21 shown, with the formation or production of the through-opening 34 in the same or a subsequent operation from the through-opening 34 or from the plane of the electrode plates 32, the projections 35 or bulges 35 bend out.

The pipe sections 36 or tubular projections 36 as projections 36 are, as in 22 shown, for example, by punching the through-openings 34 out of the electrode plates 32 with bulging or stretched.

Reference List

1

air duct housing

2

direction of air flow

3

air duct

4

air intake opening

5

air outlet opening

6

fan

7

air cleaning arrangement

7a

Air Purifier Housing

7b

air cleaning housing wall

7c

lateral air cleaning housing wall

7d

Air cleaner housing wall level of the side air cleaner housing wall

8th

UV light source

8a

UV light source assembly

9

electric field

10

fastening device

11

high voltage generator

12

electrode area

13

double-sided circuit board, circuit board

14

ladder structure

15

lamella

16

steering

17

sensor

18

electric power supply

19

contact opening

20

connector

21

contact rod

22

poetry

23

blind plug

24

power adapter

25

PSU trough, PSU housing

26

upper wall of the air duct housing, cover

27

opening

31

flow opening

31a

lace pattern

32

electrode plate

33

electrode profile

34

Through hole, recess

35

overhang, superelevation

36

piece of pipe, tubular overhang, overhang

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 102013225255 A1 [0002]

Claims (15)

Air cleaning arrangement (7) comprising at least one air cleaning housing (7a), wherein the at least one air cleaning housing (7a) has at least one air inlet opening (4) and at least one air outlet opening (5) and in the at least one air cleaning housing (7a) at least one UV light source (8) and at least one electrical field (9) generated by means of high voltage is present, with air forming an air flow and being able to flow through the at least one air inlet opening (4) into the at least one air cleaning housing (7a) and the at least one UV light source ( 8) and the at least one electric field (9) is arranged and the air can flow out of the at least one air cleaning housing (7a) through the at least one air outlet opening (5). Air cleaning arrangement (7) after claim 1 characterized in that at least one fan (6) is present, with the at least one fan (6) being arranged inside and/or outside the air cleaning housing (7a) and/or in that the at least one fan is in the region of the air inlet opening (4) or air outlet opening (5) is arranged. Air cleaning arrangement (7) according to one of Claims 1 and 2 , characterized in that the at least one air cleaner housing (7a) is pushed or inserted or integrated into at least one air duct (3) and/or that the at least one air duct (3) forms at least one air cleaner housing wall (7b) of the air cleaner housing (7a) and/ or that in the case of two or more air cleaner housings (7a), the air cleaner housings (7a) are electrically connected to one another. Air cleaning arrangement (7) according to one of the preceding claims, characterized in that the at least one UV light source (8) as at least one UV light source arrangement (8a) is strip-shaped or angled or curved and is transverse, angularly inclined, curved and/or parallel to the Flow direction (2) of the air and/or is arranged opposite one another and/or that at least one of the inner surfaces of the air cleaner housing (7a) is at least partially light-reflecting or has a light-reflecting coating. Air cleaning arrangement (7) according to one of the preceding claims, characterized in that at least one of the air cleaning housing walls (7b) has conductor tracks or other conductive structures or coatings on the outer surface and/or inner surface. Air cleaning arrangement (7) according to one of the preceding claims, characterized in that there is a high-voltage generator (11) for generating the high voltage, the high-voltage generator (11) being electrically connected to at least two electrode surfaces (12). Air cleaning arrangement (7) after claim 6 , characterized in that the electrode surfaces (12) are formed on at least partially electrically conductive and/or structured inner surfaces of two opposite air cleaner housing walls (7b) of the air cleaner housing (7a), the opposite air cleaner housing walls (7b) being approximately parallel or longitudinal to the direction of flow (2nd ) of the air and/or that the electrode surfaces (12) are arranged on at least partially electrically conductive and/or structured electrode plates (32) in the air cleaner housing (7a), the electrode plates (32) being arranged transversely and/or longitudinally and/or diagonally to the direction of flow (2) of the air and/or that the electrode surfaces (12) are arranged on at least partially electrically conductive and/or structured inner surfaces of a circumferential air cleaner housing wall (7b) of the air cleaner housing (7a) and on at least one of them arranged concentrically or centered or distributed elec rode profile (33), the at least one electrode profile (33) arranged concentrically or centered or distributed and the circumferential air cleaning housing wall (7b) being arranged approximately parallel or lengthwise to the flow direction (2) of the air. Air cleaning arrangement (7) according to one of Claims 5 until 7 , characterized in that between and at a distance from the opposite air cleaning housing walls (7b) with the electrode surfaces (12) a double-sided printed circuit board (13) is arranged at least in regions. Air cleaning arrangement (7) after claim 8 , characterized in that the double-sided printed circuit board (13) has at least one further electrode surface (12) and/or conductor structures (14) on both sides, with at least one further electrode surface (12) on each side being electrically connected to the high-voltage generator (11). Air cleaning arrangement (7) according to one of Claims 4 , 8th and 9 , characterized in that the at least one UV light source (8) or the at least one UV light source arrangement (8a) on the double-sided printed circuit board (13) and/or on at least one or on one of the opposing air cleaner housing walls (7b) and/or that the high-voltage generator (11) is arranged in the air cleaner housing (7a) or outside of the air cleaner housing (7a). Air cleaning arrangement (7) according to one of the preceding claims, characterized in that at least one lamella (15) and/or at least one flow opening (31 ) available. Air cleaning arrangement (7) after claim 11 , characterized in that the cross section of the slats (15) is roof-shaped or V-shaped or A-shaped or has at least a half-wave, with the tapered area or the crest or the trough of a slat (15) extending into the wide end or the shaft of the adjacent lamella, which is open at the bottom or at the top, overlaps and/or that the at least one flow opening (31) is arranged as a hole pattern (31a) in the lateral air cleaner housing wall (7c), the lateral air cleaner housing wall (7c) consisting of at least two spaced apart air cleaner housing wall planes ( 7d) and the air cleaning housing wall levels (7d) each have at least one flow opening (31) as a hole pattern (31a) and/or that the lamellae (15) or at least one of the lateral air cleaning housing walls (7c) or at least one of the air cleaning housing wall levels (7d) have a non-reflective surface. Air cleaning arrangement (7) according to one of the preceding claims, characterized in that a controller (16) for the at least one UV light source (8) and/or the at least one electric field (9) and/or the at least one blower (6) is present and/or that at least one sensor (17) is present and at least connected to the controller (16). Air cleaning arrangement (7) according to one of Claims 14 and 15 , characterized in that the controller (16) has at least one wireless communication interface and/or user administration. Air cleaning arrangement (7) according to one of the preceding claims, characterized in that there is a fastening device (10) and/or an electric power supply line (18).

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