DE102021208299A1 - Ventilation and/or air conditioning system for a motor vehicle - Google Patents

Abstract

The invention relates to a ventilation and/or air conditioning system (1) for a motor vehicle, having at least one air duct (2) and having at least one vent (3) which is arranged at one end of the air duct (2) and is designed for the air duct (2) directing air flowing through into a vehicle interior, with a UVC module (4) which has a radiation source (5) for generating UVC radiation, a holder (7) supporting the radiation source (5) and at least one air guiding element (12 ) for guiding the air flow to the radiation source (5). It is provided that the radiation source (5) is arranged within the air duct (2) upstream of the vent (3).

Description

The invention relates to a ventilation and/or air conditioning system, hereinafter referred to simply as the system, for a motor vehicle, with at least one air duct and with at least one vent which is arranged at one end of the air duct and is designed to direct air flowing through the air duct into a Conduct vehicle interior, with a UVC module having a radiation source for generating UVC radiation, a radiation source overlying holder and at least one air guiding element for guiding the air flow to the radiation source.

Systems of the type mentioned are already known from the prior art. For example, the disclosure document discloses CN 212242906 U a UVC module for motor vehicles, which can be attached to the outside of the air vent of an air conditioning system in order to guide air flowing out of the vent using a plurality of air guiding elements along a UVC radiation source for treating the air. The UVC radiation in particular kills or sterilizes bacteria and viruses contained in the air flow, so that only filtered air is supplied to the vehicle interior. The well-known UVC module has the advantage that it can easily be retrofitted to any motor vehicle. However, it then protrudes from the vent and prevents the air outflow direction, which can normally be set by the vent, from being no longer realizable for the air flow flowing into the vehicle interior.

From the disclosure documents U.S. 2020/03306838 A1 and CN 101839581B other UVC modules for the sterilization of air flows are known.

The object of the present invention is to improve a ventilation and/or air conditioning system, in particular to reduce flow losses and increase the efficiency of the UVC module.

The object on which the invention is based is achieved by a system having the features of claim 1 . This has the advantage that UVC radiation is evenly applied to the air flow before the air reaches the vent and thus the vehicle interior. According to the invention, the radiation source is arranged within the air duct upstream of the outflow vent. The UVC module is thus located within the system, ensuring that any air supplied to the air vent is or can be UVC-treated. In particular, the UVC module is located directly upstream of the air vent, which means that there is no further module in the air duct between the UVC module and the air vent.

The holder preferably supports the radiation source centrally in the cross section of the air duct and at a distance from a casing wall of the air duct. The radiation source is thus located in the air duct at a radial distance from the casing wall of the air duct, so that the air flow can flow around it almost completely. A direct flow around the radiation source is only not possible in the area in which the radiation source is connected to the holder. The advantageous arrangement ensures that the UVC module works particularly efficiently and treats the air flow advantageously. The casing wall is particularly preferably provided with a surface, at least in the region of the radiation source, which has a reflective effect for the UVC radiation, so that an advantageous UVC radiation distribution is brought about in the air duct.

Furthermore, it is preferably provided that the holder has a jacket wall element at a distance from the radiation source, which completely fills or covers a jacket wall opening of the air duct. The UVC module thus forms the air duct by covering or filling the shell wall opening. As a result, the air duct remains closed on the wall side and the UVC module can also be integrated in the air duct later.

The casing wall opening is preferably designed to be large enough for the radiation source to be able to be guided through. This ensures that the UVC module is easy to install. In this case, the jacket wall opening can be designed to be smaller than the radiation source in a radial projection of the radiation source onto the jacket wall opening. By tilting the UVC module when inserting the radiation source, it can still be installed in the air duct. In a preferred embodiment of the invention, the jacket wall opening is designed to be large enough for the radiation source to be able to be inserted and removed radially without having to be tilted.

Furthermore, it is preferably provided that a control device for the radiation source is arranged on the side of the jacket wall element facing away from the radiation source. As a result, the control device is advantageously arranged outside of the air duct so that the air flow is not impaired.

Furthermore, it is preferably provided that the radiation source is designed and arranged in a flow-optimized manner. This achieves the least possible air flow through the radiation source Turbulence or frictional effects are generated that could affect the airflow.

The radiation source particularly preferably has a longitudinal extension in the direction of flow that is greater than its transverse extension. As a result, the radiation source extends longer in the flow direction or in the longitudinal extension of the air duct than transversely thereto, which results in an advantageous integration of the air flow or an advantageous streamlined shape.

The radiation source is preferably in the form of a rod or a droplet in its longitudinal extent, which results in further flow advantages. In particular, this further prevents turbulence or flow resistance from occurring.

Provision is furthermore preferably made for the air guiding element to be assigned to the radiation source upstream, with the air guiding element being designed to supply a laminar air flow to the radiation source. The air guiding element is therefore not used to initially direct the air flow in the direction of the radiation source, but rather to filter out turbulence from the air flow or to convert the air flow into a laminar flow, so that the air flowing past the radiation source can be treated particularly efficiently by UVC radiation is.

The air guiding element in the air duct preferably forms a multiplicity of air guiding ducts running parallel to one another, which in particular have a honeycomb, circular or part-circular cross section. The result of this is that a possibly upstream turbulent flow is converted into a laminar flow and fed to the radiation source.

The air guiding element particularly preferably has a plurality of lamellae or ribs for forming the air guiding ducts, which protrude from the outer wall of the air duct into the air duct. The partial air ducts, for example, are separated or formed from one another by the lamellae or ribs. Optional slats or ribs serve in particular to guide the air flow past the radiation source in such a way that there is no dynamic pressure point on the inflow side of the radiation source.

• 1 einen Ausschnitt einer vorteilhaften Belüftungs- und Klimatisierungsanlage für ein Kraftfahrzeug,
• 2A bis 2D ein Luftleitelement der Anlage von 1 gemäß unterschiedlicher Ausführungsbeispiele und
• 3A bis 3D Querschnittsformen eines Luftkanals der Anlage von 1 gemäß unterschiedlicher Ausgangsbeispiele.

The invention will be explained in more detail below with reference to the drawing. to show

• 1 a section of an advantageous ventilation and air conditioning system for a motor vehicle,
• 2A until 2D an air guide element of the system from 1 according to different embodiments and
• 3A until 3D Cross-sectional shapes of an air duct of the plant from 1 according to different initial examples.

1 shows a section of an advantageous ventilation and air conditioning system 1 in a simplified longitudinal sectional view, which has an air duct 2 which is assigned to an air conditioning unit at one end and has a vent 3 at the other end or on the outlet side. The vent 3 is designed to introduce an air flow, which is guided through the air duct 2 and is in particular air-conditioned, into a motor vehicle interior. For this purpose, the outflow vent 3 preferably has pivotably mounted slats, by means of which the air outflow direction can be adjusted by a user.

A UVC module 4 is also assigned in the air duct 3 . The UVC module 4 has a radiation source 5 which is designed to generate UVC light, ie ultraviolet light in a wavelength range of in particular 280-100 nm. According to the present exemplary embodiment, the radiation source 5 is in the form of a rod with a longitudinal extent L that is many times greater than an extent of the radiation source 5 transverse to the longitudinal extent. In particular, the radiation source 5 has a circular cross section. The radiation source 5 is arranged in its longitudinal extension parallel to the direction of flow in the air duct 2 at a radial distance from a casing wall 6 of the air duct 2 . In particular, the radiation source 5 is located centrally - viewed in cross section - in the air duct 2.

The UVC module 4 also has a holder 7 through which the radiation source 5 is held and aligned on the air duct 2 . For this purpose, the holder 7 has a casing wall element 8 which completely fills a casing wall opening 9 in the casing wall 6 of the air duct 2 so that the casing wall element 8 closes the casing wall opening 9 and the air duct 2 is sealed. A projection 7` of the holder 7 extends radially from the casing wall element 8 into the air duct 2 and holds the radiation source 5 at its free end Radiation source 5 arranged.

Upstream of the radiation source 5, the direction of flow is in 1 indicated by an arrow 11, an air guide element 12 is arranged in the air duct 2. FIG. The air guiding element 12 is designed to prevent the air flow from reaching the beam to linearize the radiation source 5 or to reduce or avoid turbulence in the air flow, so that the radiation source 5 is surrounded by an at least essentially laminar air flow, as in 1 shown simplified by flow lines SL. For this purpose, the air guiding element 12 has, for example, a plurality of slats 13 which are aligned parallel to one another in order to calm or straighten the air flow. The air guiding fins 13 extend in the direction of flow and are aligned parallel to the longitudinal extension of the air duct 2 .

2A until 2D show different exemplary embodiments of the air guiding element 12, each in a cross-sectional view. The slats 13 form a plurality of partial air ducts 14 in the air guiding element 12, through which the air flow is guided. The air sub-ducts 14, such as in the embodiment of 2A shown, each have a circular cross section. According to the embodiment of 2A a central partial air channel 14_1 is present, the diameter of which essentially corresponds to the outer diameter of the radiation source 5 or is slightly larger than this. Optionally, the partial air duct 14_1 is designed to be closed, so that the entire air flow is guided through the air ducts 14, which are distributed in a ring around the air duct 14_1. In this way, in particular, the formation of a dynamic pressure area on the inflow side of the radiation source 5 is prevented.

According to another embodiment, as in 2 B shown, the air sub-ducts are honeycombed.

According to another embodiment, as in 2C shown, the partial air ducts 14 are designed in the shape of a part of a circle. For this purpose, the slats 13, as already described above, are aligned parallel to one another and each extend over the entire width of the air duct 2.

According to the embodiment of 2D the partial air ducts 14 are also designed in the form of a part circle, with a central partial air duct 14_1 being designed in the form of a honeycomb.

3A until 3D show different exemplary embodiments of the cross section of the air duct 2 itself. This can be oval-shaped, as in 3A shown, rectangular, as in 3B shown, circular, as in 3C shown, or kidney-shaped, as in 3D shown.

Reference List

1

Ventilation and air conditioning system

2

air duct

3

vents

4

UVC module

5

radiation source

6

coat wall

7

holder

7`

head Start

8th

jacket wall element

9

jacket wall opening

10

UVC control unit

11

Arrow

12

air deflector

13

air deflector

14

air part duct

14_1

air part duct

L

longitudinal extent

SL

flow line

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

• CN 212242906 U [0002]
• US202003306838A1 [0003]
• CN 101839581B [0003]

Claims (11)

Ventilation and/or air conditioning system (1) for a motor vehicle, with at least one air duct (2) and with at least one vent (3) which is arranged at one end of the air duct (2) and is designed to flow through the air duct (2). guiding air into a vehicle interior, with a UVC module (4) which has a radiation source (5) for generating UVC radiation, a holder (7) supporting the radiation source (5) and at least one air guiding element (12) for guiding the air flow to the radiation source (5), characterized in that the radiation source (5) is arranged within the air duct (2) upstream of the vent (3). plant after claim 1 , characterized in that the holder (7) supports the radiation source (5) in the cross section of the air duct (2) centrally and spaced radially from a casing wall (6) of the air duct (2). System according to one of the preceding claims, characterized in that the holder (7) has a casing wall element (8) at a distance from the radiation source (5) which completely fills or covers a casing wall opening (9) of the air duct (2). Plant according to one of the preceding claims, characterized in that the shell wall opening (9) is designed so large that the radiation source (5) can be guided through. Plant according to one of the preceding claims, characterized in that a control device (10) for the radiation source (5) is arranged on the side of the jacket wall element (8) facing away from the radiation source (5). Plant according to one of the preceding claims, characterized in that the radiation source (5) is constructed and arranged in a flow-optimized manner. Plant according to one of the preceding claims, characterized in that the radiation source (5) has a longitudinal extent (L) in the direction of flow which is greater than its transverse extent. Installation according to one of the preceding claims, characterized in that the radiation source (5) extends longitudinally in the form of a rod or a drop. System according to one of the preceding claims, characterized in that the radiation source (5) is assigned the air guiding element (12) upstream, the air guiding element (12) being designed to supply a laminar air flow to the radiation source (5). System according to one of the preceding claims, characterized in that the air guiding element (12) in the air duct (2) forms a large number of air guiding ducts (14) running parallel to one another, which in particular have a honeycomb, circular or part-circular cross-section. System according to one of the preceding claims, characterized in that the air guide element (12) for forming the air guide channels (14) has a plurality of lamellae or rib elements which protrude from the casing wall (6) of the air channel (2) into the air channel (2).

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