DE102020213415A1 - Air conditioning device and method for conditioning air - Google Patents

Abstract

The invention relates to an air treatment device (1) for treating air and a method for treating air.

Description

The invention relates to an air treatment device for treating air, with a device housing having a longitudinal center axis, a room air inlet and an air outlet and forming a flow channel for air flowing from the room air inlet to the air outlet, wherein at least one device housing is controlled and/or controlled by means of a control device in the flow channel controllable gas delivery device and a filter arrangement having at least one filter element are arranged, and wherein an air flow flowing from the room air inlet through the filter arrangement to the air outlet can be generated or is generated by the gas delivery device.

Furthermore, the invention relates to a method for treating air.

Air treatment devices are known which have a device housing which has a room air inlet and an air outlet and forms a flow channel, with a gas conveying device and a filter arrangement being arranged in the flow channel. Here, the room air is sucked in by means of the gas conveying device via the room air inlet, then flows through the filter arrangement arranged in the flow channel and flows out of the air treatment device into the room again at the air outlet. Thus, the air in the room is circulated by the known air treatment device. A disadvantage of this air treatment device is that the quality of the air treated in such air treatment devices is not particularly good.

The object of the invention is to provide an air treatment device that enables improved air treatment.

The object is achieved with an air treatment device of the type mentioned at the outset in that at least one air disinfection device that emits ultraviolet radiation is arranged in a flow channel section of the flow channel designed as an air disinfection section for disinfecting the air flowing through the air disinfection section that has an air disinfection section length, and that the device housing has a fresh air inlet , so that the air flow upstream of a filter element, a flow of fresh air can be mixed.

The advantage of this air treatment device is that the high-energy, ultraviolet radiation emitted by the air disinfection device, expediently UV-C radiation, also damages the genetic material of microorganisms and viruses, so that the air disinfection device has the ability to kill bacteria and viruses. This significantly improves the conditioning of the air flowing through the air conditioning device.

In this respect, the air disinfection device preferably has a UV lamp which emits the ultraviolet radiation. Ultraviolet radiation includes UV-A, UV-B and UV-C radiation and has a wavelength in the range between 100 nm and 400 nm. The UV-C radiation preferably emitted by the air disinfection device has a wavelength of 100 nm to 280 nm. The air disinfection device particularly preferably emits UV-C radiation with a wavelength of around 254 nm. According to several current studies, UV-C radiation of such a wavelength has a high mutagenic effect.

The air flowing through the flow channel is particularly preferably irradiated with the ultraviolet radiation over the entire flow cross section of the flow channel section designed as an air disinfection section and thus also along the entire length of the air disinfection section. The air disinfection section and expediently the length of the air disinfection section are selected and dimensioned in such a way that the air stream flowing through the air disinfection section has a sufficiently long dwell time in the air disinfection section for disinfection. In particular, the dwell time should be long enough to reach a lethal dose for viruses and/or bacteria in the airflow.

A fresh air flow is also advantageously added to the air flow upstream of a filter element. As a result, the oxygen content of the air flow and thus also in the treated air increases and ensures, for example, that the people working in a room improve their ability to concentrate and thus also the working conditions. Before fresh air is added to the air flow, the air flow preferably corresponds to a room air flow. After the air flow has been mixed with the fresh air flow, the air flow having a fresh air portion and a room air portion flows through the flow channel of the device housing to the air outlet and exits there from the air treatment device.

Between 20% and 40% of fresh air are preferably added to the air flow, preferably upstream of the first filter element. Thus, the proportion of fresh air in the air flow is in particular 20% to 40% and the proportion of room air in the air flow is correspondingly 60% to 80%. This turns one off sufficient good air quality is ensured in the room to be supplied with treated air. In particular, the proportion of fresh air in the air flow can be adjusted using a fresh air screen. By supplying fresh air, a constant oxygen concentration is preferably ensured in the room to be supplied with treated air.

This advantageously improves the treatment of the air compared to the known air treatment device, since, in addition to filtering the room air, the air flow is disinfected based on ultraviolet radiation and fresh air is supplied to the air flow.

Further advantageous configurations of the air treatment device can be found in the dependent claims.

In this regard, the filter arrangement expediently has three filter elements. The first filter element is preferably arranged between the room air inlet and the gas delivery device, the second filter element between the gas delivery device and the air outlet and the third filter element between the second filter element and the air outlet. In a particularly advantageous development of the air treatment device, the first filter element is designed as a filter having a filter class F7, the second filter element as a filter having a filter class F9 and the third filter element as a particulate filter.

Filters in filter class F7 and F9 have a degree of separation of more than 95% for coarse dust (insects, hair, sand, etc.) and a degree of separation of more than 50% for particles with a grain size between 1 µm and 10 µm. Here, filters of filter class F7 are suitable from the air flow particles with a particle size of 2.5 µm to 10 µm with a separation efficiency of more than 85%, with a particle size of 1 µm to 2.5 µm with a separation efficiency of more than 65% to 80% % and with a grain size of up to 1 µm with a separation efficiency of 50% to 65%.

Filters of filter class F9, on the other hand, are suitable for removing particles from the air flow with a particle size of 2.5 µm to 10 µm with a separation efficiency of more than 95%, with a particle size of 1 µm to 2.5 µm with a separation efficiency of more than 95% and with a grain size of up to 1 µm with a degree of separation of more than 80%.

HEPA filters are filters for separating suspended matter from the air. These are depth filters and separate particles with an aerodynamic diameter of less than 1 µm, e.g. B. bacteria and viruses, pollen, mite excrement and eggs, dust, aerosols and smoke particles. With increasing separation efficiency, HEPA filters are divided into high-performance particle filters (EPA = Efficient Particulate Air), HEPA filters (High-Efficiency Particulate Air/Arrestance) and high-performance HEPA filters (ULPA = Ultra-Low Penetration Air). The so-called HEPA particulate filters are particularly preferably used in the air treatment device.

Due to the advantageous filter arrangement having at least one filter element designed as a filter, the air flowing through the air treatment device as an air flow is subjected to significantly improved purification.

According to a further advantageous embodiment of the air treatment device, the air disinfection section having an air disinfection section length is arranged between two filter elements, preferably between the first and the second filter element. This ensures that coarse dust (insects, hair, sand, etc.) is separated shortly after it enters the air treatment device, so that the air treatment device, and in particular the gas conveying device, is protected from this and thus long-lasting and maintenance-free operation of the air treatment device can also be guaranteed is.

Furthermore, a further development of the air treatment device is characterized in that a nebulizer, which is expediently designed as an ultrasonic nebulizer, is arranged in the flow channel. For example, the nebulizer atomizes a liquid such as water and/or fragrances dissolved in a liquid, whereby moisture and/or a pleasant fragrance can be added to the conditioned air.

In addition, the nebulizer is also suitable for distributing a disinfectant, in particular by atomization, within the flow channel of the air treatment device. The disinfectant discharged in the flow channel mixes with the air flow flowing through it and disinfects at least one flow section of the flow channel of the air treatment device. Expediently, the treated air emerging from the air outlet can discharge the disinfectant from the air treatment device, so that a room to be supplied with the treated air can also be disinfected over its surface or is disinfected. By distributing disinfectant in the flow channel, in addition to filtering and physical disinfection of the air to be treated using the air disinfection device, a chemical disinfection of the air treatment device and/or the room to be supplied with treated air.

In order to further improve the air treatment device, the device housing has a first housing section having the room air inlet and a second housing section having the air outlet, the second housing section having the fresh air inlet. The device housing is preferably elongate and the first and the second housing section are preferably arranged on opposite housing ends of the device housing. By assigning the room air inlet and the air outlet to different housing sections of the device housing, an essentially semicircular flow from the air outlet to the room air inlet is preferably generated within a room to be supplied with treated air, corresponding to a circulation movement. Advantageously, the room air can be efficiently circulated here.

According to an additional advantageous development of the air treatment device, the air outlet has an air guiding element expediently designed as a fixed lamella. In this regard, the air guiding element is advantageously arranged at an angle to the longitudinal central axis, preferably at an angle of less than or equal to 90°, in particular at an angle of 45°. This further improves the circulation movement of the air within a room to be supplied with treated air, which is preferably designed as a substantially semicircular flow from the air outlet to the room air inlet, so that the room air can be efficiently circulated or circulated.

According to a further advantageous embodiment of the air treatment device, it has a fresh air flow duct having the fresh air inlet and a fresh air outlet. The fresh air outlet of the fresh air flow duct opens into the flow duct, so that the fresh air flow can flow through the fresh air outlet into the flow duct for mixing with the air flow. The fresh air outlet can open into the flow channel at any desired position, preferably in front of the first filter element of the filter arrangement.

The fresh air flow channel is expediently formed by a flow channel wall and a part of the device housing. The fresh air flow duct preferably extends within the device housing at least in sections parallel and adjacent to the flow duct. The flow direction of the fresh air in the fresh air flow channel is opposite to the flow direction of the air flow in the flow channel.

More preferably, the fresh air flow channel is at least partially integrated in the device housing. The arrangement of the flow duct within the device housing results in a compact design of the air treatment device, as a result of which fresh air flow duct sections lying outside the device housing are avoided or can be avoided. However, the fresh air flow duct can also have fresh air flow duct sections which are arranged in sections outside of the device housing and which are designed, for example, as fresh air supply pipes.

The fresh air flow duct particularly preferably has a fresh air aperture that can be controlled and/or regulated by means of the control device for adjusting the fresh air flow. The fresh air screen can be arranged within the fresh air flow duct at the fresh air inlet and/or in the fresh air flow duct and/or at the fresh air outlet. In order to set the flow of fresh air, the fresh air screen can expediently be moved by the control device from a closed position to at least one open position and vice versa.

The air treatment device is further characterized in that it has a heat exchanger which is preferably arranged in the flow channel between the gas delivery device and the second filter element and is suitable for supplying or dissipating heat to the air flow and/or fresh air flow. The heat exchanger makes it possible to heat or cool the air flow and/or fresh air flow according to a preset temperature, for example the room temperature of the room to be supplied with treated air. As a result, the air treatment device essentially additionally offers the function of an air conditioning system.

The air treatment device is further improved in that it has at least one functional module on which the at least one filter element of the filter arrangement and/or the gas delivery device and/or the air disinfection device and/or the control device and/or the nebulizer are optionally arranged. The at least one functional module is preferably arranged in the air disinfection section of the flow channel. The functional module is particularly preferably arranged on guide rails in order to be able to easily pull out the functional module on the air treatment device. This allows for a flexible and modular design of the air treatment device.

According to an additional advantageous embodiment, the air treatment device has sensors, in particular sensors that measure the oxygen content and/or the temperature and/or the humidity of the room air and/or the air flowing through the flow channel. As a result, important parameters of the room air or the air flow, such as the oxygen content and/or the temperature and/or the humidity, can be set directly by means of the control device.

According to an additional advantageous development of the air treatment device, the device housing of the air treatment device is designed to be soundproofed or soundproof. This minimizes the noise that may be generated by the gas conveying device.

In addition, the object is achieved with a method of the type mentioned at the outset in that the method for treating air includes the method steps of sucking in room air, sucking in fresh air, mixing the fresh air into the room air, filtering the room air and fresh air mixed to form the air flow, and disinfecting the mixed air flow by means of ultraviolet radiation, and outflow of the treated air.

The advantage of this method is that the high-energy, ultraviolet radiation emitted by the air disinfection device, expediently UV-C radiation, also damages the genetic material of microorganisms and viruses, so that the air disinfection device has the ability to kill bacteria and viruses. The air flowing through the flow channel is particularly preferably irradiated with the ultraviolet radiation over the entire flow cross section of the air disinfection section and thus also along the entire length of the air disinfection section. The air disinfection section and expediently the length of the air disinfection section is selected such that the air stream flowing through the air disinfection section has a sufficiently long dwell time in the air disinfection section for disinfection. This significantly improves the conditioning of the air flowing through the air conditioning device.

A fresh air flow is also advantageously added to the air flow upstream of a filter element. This increases the oxygen content of the air flow and, for example, improves the ability of people working in a room to concentrate and thus also the working conditions. Before fresh air is added to the air flow, the air flow preferably corresponds to a room air flow. After the air flow has been mixed with the fresh air flow, the air flow, which has a fresh air component and a room air component, flows through the flow channel of the device housing to the air outlet and exits there from the air treatment device.

Between 20% and 40% of fresh air are preferably added to the air flow, preferably upstream of the first filter element. Thus, the proportion of fresh air in the air flow is in particular 20% to 40% and the proportion of room air in the air flow is correspondingly 60% to 80%. This ensures adequate air quality in the room to be supplied with treated air. In particular, the proportion of fresh air in the air flow can be adjusted using a fresh air screen. By supplying fresh air, a constant oxygen concentration is preferably ensured in the room to be supplied with treated air.

A room volume of a room to be supplied with treated air is expediently specified in the method, so that the entire air volume of the room air is circulated at least six times per hour. For this purpose, the air treatment device expediently has at least one powerful gas delivery device that can be controlled and/or regulated by means of the control device. Each gas conveying device can preferably convey a volume flow of in particular 2000 m ³ /h to 6000 m ³ /h through the air treatment device. In this way, a very high air quality is ensured at all times in a room to be supplied with treated air.

According to an additional advantageous embodiment of the method, the nebulizer distributes a fluid in the flow channel, in particular a liquid configured as a disinfectant, with the flow channel, the gas delivery device and/or a part of the filter arrangement being disinfected by the disinfectant. The nebuliser is preferably controlled and/or regulated by means of the control device. In this case, a time switch device is expediently used so that a point in time for the distribution of the fluid, in particular the liquid, can be selected or is selected at which no people are present within the room to be supplied with treated air. A night-time rinsing mode can be selected in a particularly preferred manner.

• 1 eine perspektivische Darstellung einer ersten Ausführungsform einer Luftaufbereitungsvorrichtung,
• 2 eine Seitenansicht von rechts auf die erste Ausführungsform der Luftaufbereitungsvorrichtung,
• 3 eine Schnittdarstellung von rechts durch die Schnittebene A durch die erste Ausführungsform der Luftaufbereitungsvorrichtung,
• 4 eine perspektivische Darstellung der ersten Ausführungsform der Luftaufbereitungsvorrichtung mit einem Funktionsmodul,
• 5 eine erste Ausführungsform eines Funktionsmoduls,
• 6 eine zweite Ausführungsform eines Funktionsmoduls,
• 7 eine perspektivische Darstellung einer zweiten Ausführungsform einer Luftaufbereitungsvorrichtung,
• 8 eine Vorderansicht der zweiten Ausführungsform der Luftaufbereitungsvorrichtung bei nicht gezeigter Vorderwand,
• 9 eine perspektivische Darstellung einer dritten Ausführungsform einer Luftaufbereitungsvorrichtung,
• 10 eine dritte in der dritten Ausführungsform der Luftaufbereitungsvorrichtung verwendete Ausführungsform eines Funktionsmoduls und
• 11 eine perspektivische Darstellung einer vierten Ausführungsform einer Luftaufbereitungsvorrichtung mit einem Funktionsmodul.

The invention is explained in more detail below with reference to the accompanying drawing and is shown in it

• 1 a perspective view of a first embodiment of an air treatment device,
• 2 a side view from the right of the first embodiment of the air treatment device,
• 3 a sectional view from the right through the section plane A through the first embodiment of the air treatment device,
• 4 a perspective view of the first embodiment of the air treatment device with a functional module,
• 5 a first embodiment of a function module,
• 6 a second embodiment of a function module,
• 7 a perspective view of a second embodiment of an air treatment device,
• 8th a front view of the second embodiment of the air treatment device with the front wall not shown,
• 9 a perspective view of a third embodiment of an air treatment device,
• 10 a third embodiment of a functional module used in the third embodiment of the air treatment device and
• 11 a perspective view of a fourth embodiment of an air treatment device with a functional module.

Unless otherwise specified, the following description relates to all of the embodiments of an air treatment device 1 for the treatment of air illustrated in the drawing.

1 shows a perspective view of a first embodiment of an air treatment device 1 that can preferably be set up on a wall of a room. The air treatment device 1 has a longitudinal center axis XX, a room air inlet 2 and an air outlet 3, and a flow channel 4 for air flowing from the room air inlet 2 to the air outlet 3 forming device case 5 .

The device housing 5 has a multi-part front wall 6a, 6b and 6c, side walls 7, a rear wall 8, a floor 9 and a cover 10. The individual front walls 6a and 6c designed as doors 11a and 11c in the first embodiment can be pivoted about a pivot axis Y-Y arranged so that each designed as a door 11a and 11c front wall 6a and 6c can be opened. The front 6b has a display 12 of a control device 13 and forms the cover 14 for a functional module 15 that can be pulled out of the device housing 5.

The room air inlet 2 is formed by a plurality of slits 16 in the first embodiment. The slots 16 are arranged on the two side walls 7 and on the front wall 6a designed as a door 11a. Other configurations of the room air inlet 2 are conceivable, in particular also as perforated sheet metal having bores.

The air outlet 3 has an air guiding element 17 . The air guide element 17 arranged at an angle to the longitudinal center axis X-X is designed as a fixed lamella 18, which deflects the treated air exiting the air outlet 3 into the room by an angle α of 90°. This creates a circulating movement 19 of the air within the room to be supplied with treated air, which is preferably designed essentially as a semicircular flow from the air outlet 3 to the room air inlet 2, so that the room air can be circulated efficiently by means of the air treatment device 1.

In the 2 1 shows a side view of the first embodiment of the air treatment device 1 from the right, with a sectional plane A intersecting the longitudinal central axis XX and running parallel to the side walls 7 of the device housing 5 .

The device housing 5 has a first housing section 20 having the room air inlet 2 and a second housing section 21 having the air outlet 3. The first housing section 20 is arranged in the area of the bottom 9 of the device housing 5 and the second housing section 21 in the area of the cover 10 of the device housing 5 . In addition to the air outlet 3 , the second housing section 21 also has a fresh air inlet 22 arranged in the cover 10 for the supply of fresh air to the air treatment device 1 .

Preferably, the device housing 5 is elongate and the first and the second housing section 20, 21 are arranged at housing ends 23 of the device housing 5 lying opposite one another. By assigning the room air inlet 2 and the air outlet 3 to different housing sections 20, 21 of the device housing 5, an essentially semicircular flow from the air outlet 3 to the room air inlet 2 is preferably generated within a room to be supplied with treated air, corresponding to the circulation movement 19.

A sectional view from the right through the section plane A through the first embodiment Air treatment device 1 is in 3 pictured. From the room air inlet 2 arranged in the first housing section 20 to the air outlet 3 arranged in the second housing section 21, the air treatment device 1 has, in the flow direction of the air, a first filter element 24a of a filter arrangement 25 comprising three filter elements 24, a gas delivery device arranged on the pull-out functional module 15 and designed as a blower 26 27 and an air disinfection device 29 designed as a UV-C lamp 28, which emits ultraviolet radiation, and a second and third filter element 24b and 24c of the filter arrangement 25 comprising the three filter elements 24.

The first filter element 24a is designed as a filter 30a having a filter class F7, the second filter element 24b is designed as a filter 30b having a filter class F9, and the third filter element 24c is designed as a particulate filter 31. The filters 30a and 30b in filter class F7 and F9 have a degree of separation of more than 95% for coarse dust, such as insects, hair, sand, etc., and a degree of separation of at least greater for particles with a grain size between 1 μm and 10 μm 50% up.

In this case, filters 30a of filter class F7 are suitable from the air flow for particles with a grain size of 2.5 μm to 10 μm with a separation efficiency of more than 85%, with a grain size of 1 μm to 2.5 μm with a separation efficiency of more than 65% 80% and with a particle size of up to 1 µm with a separation efficiency of 50% to 65%.

Filter 30b of filter class F9, however, are suitable from the air flow particles with a grain size of 2.5 microns to 10 microns with a degree of separation greater than 95%, with a grain size of 1 micron to 2.5 microns with a degree of separation greater than 95% and with a particle size of up to 1 µm with a degree of separation of more than 80%.

The HEPA filter 31 is a filter 32 suitable for separating suspended matter from the air. This is one of the depth filters and separates particles with an aerodynamic diameter of less than 1 μm, e.g. B. bacteria and viruses, pollen, mite excrement and eggs, dust, aerosols and / or smoke particles. With increasing separation efficiency, particulate filters 31 are divided into high-performance particulate filters (EPA=Efficient Particulate Air), particulate filters (HEPA=High-Efficiency Particulate Air/Arrestance) and high-performance particulate filters (ULPA=Ultra-Low Penetration Air). The so-called HEPA particulate filters are particularly preferably used in the air treatment device 1 .

In other realized embodiments, the filter arrangement 25 expediently also has high-performance particle filters and/or high-performance particulate filters.

The high-energy, ultraviolet radiation emitted by the air disinfection device 29 is expediently UV-C radiation, which can damage the genetic material of microorganisms and viruses, so that the air disinfection device 29 has the ability to kill bacteria and viruses. This significantly improves the conditioning of the air flowing through the air conditioning device 1 . The UV-C radiation emitted by the air disinfection device 29 has a wavelength of 100 nm to 280 nm. The air disinfection device 29 particularly preferably emits UV-C radiation with a wavelength of around 254 nm.

The air flowing through the flow channel 4 is irradiated with the ultraviolet radiation over the entire flow cross section 33 of the flow channel section 35 designed as an air disinfection section 34 and thus also along the entire length 36 of the air disinfection section. The air disinfection section 34 is arranged between the two filter elements 24a and 24b. The air disinfection section 34 and expediently the air disinfection section length 36 are selected such that the air stream flowing through the air disinfection section 34 has a sufficiently long dwell time in the air disinfection section 34 for disinfection.

A fresh air flow duct 38, which has the fresh air inlet 22 and a fresh air outlet 37, runs parallel to the flow duct 4 on the rear wall 8 of the device housing 5. In this case, the fresh air flow duct 38 is through a flow duct wall 39 and part of the device housing 5, namely part of the side walls 7 in the first embodiment and the rear wall 8 formed. From the fresh air inlet 22 arranged in the cover 10, the fresh air flow is conducted or deflected by means of a funnel-shaped component 40 in the direction of the rear wall 8, from where the fresh air flow is directed via a fresh air aperture 41, which can be controlled and/or regulated by means of the control device 13, in order to adjust the fresh air flow in the direction of the fresh air outlet 37 flows. The fresh air flow channel 38 is completely integrated in the device housing 5 in the first embodiment.

The arranged on the functional module 15, designed as a blower 26 gas delivery device 27 sucks on the one hand via the room air inlet 2 room air from a room to be supplied with treated air and on the other hand fresh air, esp e.g. from outside a building via the fresh air inlet 22 . In the first embodiment, the room air and fresh air that are sucked in are mixed with one another upstream of the first filter element 24a. When flowing through the air treatment device, the air is treated by the corresponding devices, such as the filter arrangement 25 and the air disinfection device 29 .

The power connection box 42 for the power supply of the air treatment device 1 is arranged between the first filter element 24a and the gas conveying device 27 .

4 shows a perspective view of the first embodiment of the air treatment device 1 with a functional module 15 pulled out of the flow channel 4 of the device housing 5. For the sake of simplicity, the guide rails 43 arranged on an inner surface of the side walls 7 for pulling out or pushing in the functional module 15 into the flow channel 4 of the device housing 5 are not fully represented.

5 12 shows a first embodiment of a functional module 15. In addition to the gas conveying device 27 embodied as a fan 26, the functional module 15 has the air disinfection device 29 embodied as a UV-C lamp 28 and the control device 13.

In 6 a second embodiment of a function module 15 is shown. In contrast to the first embodiment of the functional module 15, the second embodiment of the functional module 15 shows a UV-C light 28 designed as two fluorescent tubes 44 and having an air disinfection device 29.

In addition, the second embodiment of the functional module 15 has a nebulizer 46 designed as an ultrasonic nebulizer 45 , which is arranged correspondingly in the flow channel 4 of the device housing 5 when the functional module 15 is pushed into the device housing 5 .

7 12 depicts a perspective view of a second embodiment of an air treatment device 1. FIG. In contrast to the first embodiment, the air treatment device 1, which is set up on feet 47 and can be set up in the room, has not only the room air inlets 2 in the side walls 7 of the device housing 5 but also a room air inlet 2 arranged in the floor 9. In this embodiment too, the room air inlet 2 is in the form of slots 16 educated.

In the 8th a front view of the second embodiment of the air treatment device 1 is shown with front walls 6 not shown. A differential pressure sensor 48 for measuring the flow rate of the air flow is arranged downstream of the gas conveying device 27 . The flow velocity of the air flowing through the flow channel 4 is preferably between 2 m/s and 4 m/s upstream of the gas conveying device 27 and between 6 m/s and 10 m/s downstream of the gas conveying device 27 .

9 shows a perspective view of a third embodiment of an air treatment device 1 which, in contrast to the first embodiment, has two gas conveying devices 27 arranged next to one another as blowers 26 on the functional module 15 . The two gas conveying devices 27 bring about an increase in the volume flow of the air flowing through the flow channel 4 .

10 provides a third embodiment of an in 9 An air disinfection device 29 embodied as a UV-C lamp 28 comprising two fluorescent tubes 44 is arranged downstream of the two gas conveying devices 27 arranged next to one another and designed as a blower 26 on the inner surface 49 of the front wall 6b. The air disinfection device 29 emits an ultraviolet ray for disinfecting the air flowing through the air disinfection section 34 .

A perspective view of a fourth embodiment of an air treatment device 1 with a functional module 15 is shown in 11 shown. In contrast to the first embodiment of the air treatment device 1, in the fourth embodiment of the air treatment device 1 in the flow channel 4 between the gas delivery device 27 and the second filter element 24b of the filter arrangement 25 there is a heat exchanger 52 which has an inlet line 50 and an outlet line 51 for a heat-transporting medium is suitable for supplying or dissipating heat to the air flow in order to heat or cool it.

In order to control and/or regulate the heat exchanger 52 of the air treatment device 1, the air treatment device 1 has a sensor 53 suitable for measuring the room temperature, for example a thermocouple or the like. In addition, the air treatment device 1 has a sensor 54 which is suitable for measuring the humidity of the room air and thereby carrying out a corresponding control and/or regulation by means of the control device 13 .

In another realized embodiment of the air treatment device 1, the device housing 5 of the air treatment device 1 is designed to be soundproofed or soundproof.

Claims (21)

Air conditioning device (1) for conditioning air, having a longitudinal center axis (XX), a room air inlet (2) and an air outlet (3) and a flow channel (4) for air flowing from the room air inlet (2) to the air outlet (3). forming device housing (5), wherein at least one gas conveying device (27) that can be controlled and/or regulated by means of a control device (13) and a filter arrangement (25) having at least one filter element (24) are arranged in the flow channel (4), and wherein the gas conveying device (27) can generate or generates an air flow flowing from the room air inlet (2) through the filter arrangement (25) to the air outlet (3), characterized in that in a flow channel section (35) of the flow channel (4 ) at least one air disinfection device (29) emitting ultraviolet radiation for disinfecting the air disinfection section through the one tts length (36) having air disinfection section (34) flowing air is arranged and that the device housing (5) has a fresh air inlet (22), so that the air flow upstream of a filter element (24) a fresh air flow can be admixed. Air treatment device (1) after claim 1 , characterized in that the filter arrangement (25) has three filter elements (24a, 24b, 24c). Air treatment device (1) after claim 2 , characterized in that the first filter element (24a) between the room air inlet (2) and the gas delivery device (27), the second filter element (24b) between the gas delivery device (27) and the air outlet (3) and the third filter element (24c) between the second filter element (24b) and the air outlet (3) is arranged. Air treatment device (1) after claim 2 or 3 , characterized in that the first filter element (24a) as a filter class F7 having filter (30a), the second filter element (24b) as a filter class F9 having filter (30b) and the third filter element (24c) as a particulate filter ( 31) trained filter (32) is formed. Air treatment device (1) according to one of the preceding claims, characterized in that the air disinfection section (34) is arranged between two filter elements (24), preferably between the first and the second filter element (24a, 24b). Air treatment device (1) according to one of the preceding claims, characterized in that a nebulizer (46) which is expediently designed as an ultrasonic nebulizer (45) is arranged in the flow channel (4) and/or in the fresh air flow channel (38). Air treatment device (1) according to one of the preceding claims, characterized in that the device housing (5) has a first housing section (20) having the room air inlet (2) and a second housing section (21) having the air outlet (3), the second housing section (21) has the fresh air inlet (22). Air treatment device (1) according to one of the preceding claims, characterized in that the air outlet (3) has an air guide element (17) expediently designed as a fixed lamella (18). Air treatment device (1) after claim 8 , characterized in that the air guiding element (17) is arranged at an angle to the longitudinal central axis (XX), preferably at an angle (a) of less than or equal to 90°, in particular at an angle (a) of 45°. Air treatment device (1) according to one of the preceding claims, characterized in that the air treatment device (1) has a fresh air flow channel (38) having the fresh air inlet (22) and a fresh air outlet (37). Air treatment device (1) after claim 10 , characterized in that the fresh air flow channel (38) is formed by a flow channel wall (39) and a part of the device housing (5). Air treatment device (1) after claim 10 or 11 , characterized in that the fresh air flow channel (38) is at least partially integrated in the device housing (5). Air treatment device (1) according to one of Claims 10 until 12 , characterized in that the fresh air flow channel (38) has a means of the control device (13) controllable and / or adjustable fresh air screen (41) for adjusting the fresh air flow. Air treatment device (1) according to one of the preceding claims, characterized in that the air treatment device (1) has a heat exchanger (52) which is preferably arranged in the flow channel (4) between the gas conveying device (27) and the second filter element (24b) and is suitable supply or dissipate heat to the air flow and/or fresh air flow. Air treatment device (1) according to one of the preceding claims, characterized in that the air treatment device (1) has at least one functional module (15) on which the at least one filter element (24) of the filter arrangement (25) and/or the gas delivery device (27) and/or the air disinfection device (29) and/or the control device (13) and/or the nebuliser (46) are arranged. Air treatment system (1) according to one of the preceding claims, characterized in that the air treatment device (1) has sensors (48, 53, 54), in particular sensors (48, 53, 54) which measure the oxygen content and/or the temperature and/or measure the humidity of the room air and/or the air flow flowing through the flow channel (4). Air treatment device (1) according to one of the preceding claims, characterized in that the device housing (5) of the air treatment device (1) is designed to be soundproofed or soundproof. Method for treating air according to one of the preceding claims, comprising the method steps: - suction of room air, - intake of fresh air, - mixing fresh air into the room air, - filtering of the air flow mixed room air and fresh air, - disinfecting the mixed air flow by means of ultraviolet radiation, and - Outflow of the treated air. procedure after Claim 18 , characterized in that a room volume of a room to be supplied with treated air is specified, so that the room air is circulated at least six times per hour. procedure after Claim 18 or 19 , characterized in that the air flow, preferably upstream of the first filter element (24), between 20% to 40% fresh air are added. Method according to any of the preceding claims 18 until 20 , characterized in that the nebulizer (46) distributes a fluid in the flow channel (4), in particular a liquid designed as a disinfectant, the flow channel (4), the gas delivery device (27) and/or a part of the filter arrangement (25 ) to be disinfected.

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