EP1673246A1 - Component for a device for air-conditioning the inside of a vehicle and device for air-conditioning the inside of a vehicle - Google Patents

Abstract

The invention relates to a component (4), especially a hybrid component, for a device (1) for air-conditioning the inside of a vehicle. Said component comprises a metal base body (6) which is at least partially covered with plastic (K), whereby the cavity thereof forms a flow channel (8) for a cross-flow medium; also comprising at least one flow control device (12) which controls the amount of flow of the medium which is integrated into said flow channel. The invention also relates to a device (1) for air-conditioning the inside of a vehicle by means of an air-conditioning system (2) and a component (4) connected to the air-conditioning system (2).

Description

 BEHR GmbH & Co. KG Mauserstrasse 3, 70469 Stuttgart

Component for a device for air conditioning a vehicle interior and device for air conditioning a vehicle interior

The invention relates to a component, in particular a hybrid component for a vehicle carrier, which is used as a flow channel for a device for air conditioning a vehicle interior. Furthermore, the invention relates to a device for air conditioning a vehicle interior with such a component and an air conditioning system.

Carriers formed from pipes, for. B. cross members known, which consist of metal and have correspondingly large wall thicknesses. The wall thicknesses are designed to be sufficiently thick for sufficient form, bending, buckling and torsional rigidity as well as for sufficient compressive strength. The cross member, which is designed as a tubular or hollow profile, is suitable in principle for air guidance, for example from an air conditioning system arranged centrally in the front area of the vehicle and the air guidance to side outlets.

Such a cross member is known for example from DE 100 64 522 A1. In order to reduce weight, the cross member is made of a lightweight material, in particular of a light metal in the manner of a shell construction.

BESTATIGUNGSKOPIE partly or basic body, formed, in which a plastic core forming at least one channel is arranged for sufficient rigidity and compressive strength of the cross member. The duct is provided with several openings for air tapping in order to exit the air flow.

To distribute the air to be conducted from the air conditioning system into the vehicle interior via the air duct in a mixing chamber arranged between the air conditioning system and the air duct, a ventilation flap is usually provided, which regulates the amount, distribution, of the air flowing into the air duct from the air conditioning system. Shutdown and / or diversion controls. In addition, flaps for adjusting the amount of air flowing into the vehicle interior are provided on the air taps opening directly into the vehicle interior. Such an arrangement of the ventilation flap in the mixing chamber requires a large amount of space.

The invention is therefore based on the object of specifying a component which can be used as an air duct for air conditioning a vehicle interior and has a particularly simple and space-saving construction. Furthermore, a particularly simple device for air conditioning the vehicle interior with such a component is to be specified.

The object is achieved in a component by the features of independent claim 1. The object relating to the device for air conditioning a vehicle interior is solved by the features of independent claim 13.

Advantageous developments of the invention are the subject of the dependent claims. The invention is based on the consideration that due to the spatial arrangement of the air conditioning system, the mixing chamber and the air duct connected to it along the longitudinal axis (also called the X axis) of the vehicle, the installation space of the mixing chamber is limited and by the arrangement of the ventilation flap in the mixing chamber requires too much space, which should be reduced. Therefore, existing space should be used particularly easily. For this purpose, it is provided that, in the case of a component which comprises a metallic base body which is at least partially lined with plastic and whose cavity forms a flow channel for a medium flowing through, the cavity of the base body is used for integrating a flow control device for controlling the flow rate of the medium. The flow control device is used, in particular, for controlling an air flow that is led into an interior of a vehicle by an air conditioning system of a vehicle and is provided for temperature control of the interior of the vehicle. With the help of the flow control device, the air flow or the flow rate of the air flow through the flow channel can be completely closed or opened or brought into any intermediate position. This means that the flow rate can be set to zero or the flow channel is opened at most for the air flow, ie the flow rate of the air flow through the flow channel is set to a maximum. The air flow can also be redirected.

Such a flow control device, which is arranged directly in the flow channel instead of in the mixing chamber, makes use of the installation space already used, so that by moving the arrangement of the flow control device from the mixing chamber into the flow channel, the installation space of the mixing chamber can be reduced or the mixing room of the air conditioning system is enlarged. The metallic base body is expediently provided with a plurality of flow openings for the entry and / or exit of the medium, e.g. B. fresh air, cold air and / or warm air, which are arranged laterally, centrally, above and / or below. The side flow openings are used for ventilation of the side windows and the side of the vehicle interior. The central flow opening, which can be divided, serves to ventilate the front area. The upward and / or downward flow openings serve to ventilate the footwell and / or the windscreen. Depending on the setting of an air conditioning system connected to the component, individual flow openings can be completely closed and / or opened or partially closed and / or opened.

For an arrangement of the flow device that saves installation space as possible, it is preferably arranged in a transition region between two flow openings. In one possible embodiment of the component, the flow control device is preferably arranged between a central flow opening and a lateral flow opening.

Advantageously, the base body, which is partially lined with plastic, can be perforated at least in some areas. This is expediently carried out, for example, in an opening area. Such a base body has the particular advantage of saving weight and / or strengthening the structure.

For an air flow or air distribution that controls both flow openings, the axis of rotation of the flow control device expediently runs perpendicular to the flow opening. The arrangement of the axis of rotation in the flow channel depends crucially on the air distribution between one and the other flow opening. Alternatively, the axis of rotation of the flow control device can be horizontal to the flow opening. course. In this exemplary embodiment, the axis of rotation is preferably mounted centrally and arranged transversely to the flow opening.

The flow control device is designed as a control flap, in particular as a swing flap, a roller flap or a butterfly flap. Alternatively, the flow control device can be used as a roller conveyor cassette, a blind cassette, a V-flap, a double flap, e.g. B. a barn door flap.

In order to prevent the medium, in particular air, from flowing back into the air conditioning system, the flow control device is assigned at least one partition. When the flow control device is open, the partition wall prevents the air from flowing back into the air conditioning system, in particular into the mixing chamber.

Depending on the type and function as well as the arrangement of the flow control device, in particular the control flap, it can comprise, for example, at least two deflection elements arranged around an axis of rotation, one of the deflection elements between a first position that completely closes the central flow opening and a second position that completely opens the central flow opening is arranged to be adjustable and the other deflection element is arranged to be adjustable between a third position which completely closes the lateral flow opening and a fourth position which fully opens the lateral flow opening. With such an arrangement of the flow control device, in addition to an arrangement that saves as much installation space as possible, there is also a structure that saves components, in particular flow control elements.

For the most flexible adjustment of the air distribution, e.g. B. in the side flow channel or forward in the front area, the deflection k elements arranged separately adjustable. Alternatively, the deflection elements can be coupled and thus adjusted depending on one another. In a preferred embodiment, the deflection elements can be moved symmetrically and / or asymmetrically relative to one another. For example, the deflection elements, eg. B. flaps or wings, symmetrically, that is arranged together with the opening angle constant relative to each other about the axis of rotation. Alternatively, the deflection elements can be arranged so as to be movable relative to one another in any position with an opening angle that can be set as desired.

For the simplest possible structure of the component and the simplest possible assembly, the flow control device is designed as a separate prefabricated module. As a result, a flow control device can subsequently be integrated into an already existing vehicle in a component designed as a flow channel, in particular a hybrid component, whereby the flap in the mixing chamber can be dispensed with and a larger mixing space is created.

In the device for air conditioning the vehicle interior with an air conditioning system and a component connected to the air conditioning system, the component comprises a metallic base body, which is at least partially lined with plastic, the cavity of which forms a flow channel for a medium flowing through, in particular air, and in which at least one flow control device for control the flow rate of the medium is integrated. The flow control device is arranged, for example, in the component in its connection area to the air conditioning system. In other words, the flow control device is arranged in the transition area from the air conditioning system to the flow channel in the component itself.

The base body, which is partially lined with plastic, can advantageously be perforated at least in some areas. expediently this is done, for example, in an opening area. Such a base body has the particular advantage of saving weight and / or strengthening the structure.

In general, the component designed as a flow channel is arranged in the center of the air conditioning system, the flow channel running to the side and being provided with a plurality of openings for the entry and / or exit of the medium. The flow control device is preferably in a transition region between two flow openings, e.g. B. between a central opening, in particular a central nozzle, and a side opening, in particular a side nozzle, of the flow channel.

The advantages achieved by the invention are, in particular, that in a hybrid component designed as a flow channel, in which a flow control device is integrated, when used in an air conditioning system of a vehicle, a particularly compact and space-saving design of a device for air conditioning the vehicle interior is made possible. Due to such a compact and space-saving design, the weight is correspondingly low. With such a component with an integrated flow control device, the space already used is also used several times; the component is therefore particularly suitable for use as an air duct for an air conditioning system in a vehicle.

Embodiments of the invention are explained in more detail with reference to a drawing. In it show:

FIG. 1 schematically shows a perspective illustration of a device for air conditioning with an air conditioning system and with a component designed as a flow channel and connected to the air conditioning system, FIG. 2 shows schematically an alternative embodiment of a device for air conditioning with an alternative embodiment for the component,

FIGS. 3 to 5 schematically show a cross section through a device in the connection area of the air conditioning system and component with different embodiments for a flow control device arranged in the connection area, and

FIGS. 6 to 13 schematically show a cross section through the component in a flow opening area with different embodiments for a flow control device arranged in the flow opening area.

Corresponding parts are provided with the same reference symbols in all figures.

A device 1 for air conditioning a vehicle interior is shown schematically in FIG. 1. The device 1 is installed, for example, in a vehicle and regulates an air flow directed into the vehicle interior by an air conditioning system 2. For this purpose, the device 1 comprises the air conditioning system 2, to which a component 4 designed as a flow channel is connected.

The component 4 has a base body 6, which is preferably made of sheet metal, in particular of a light metal sheet, for. B. from aluminum sheet, magnesium sheet or fine steel sheet is formed. The base body 6, for example formed from two superimposed elements E, is designed in the exemplary embodiment in the closed state as a hollow profile, in particular as a tubular hollow profile. Alternatively, the base body 6 also be designed as a hollow profile with a box-like cross-section and / or at least partially perforated. In one possible embodiment with a box-shaped cross section, the base body 6 is formed from two elements E, for example a U-profile or a lower shell and a cover.

The base body 6 is provided on the inside with plastic K. The plastic K can be added, inserted or molded in the manner of a plastic liner. In the closed state, the base body 6, which is at least partially lined with the plastic K, serves as a flow channel 8, in particular as a flow channel for guiding a medium, e.g. Air conditioning system 2.

The air conditioning system 2 generally comprises a blower for fresh air supply, a filter for air purification, an evaporator as part of a refrigeration cycle, a radiator as part of a heating circuit, a temperature control device and a mixing device for temperature control of the air to be supplied to the vehicle interior, in a manner not shown in detail , which is guided into the flow channel 8 of the component 4.

The component 4 is provided with a plurality of flow openings S1 to S8 for air conditioning the vehicle interior, of which the flow openings S1 to S5 open laterally, centrally and / or forward into the vehicle interior. As an alternative or in addition, further flow openings (not shown in detail) can open upwards and / or downwards, in particular into the windshield region or the footwell of the vehicle interior.

The flow opening S8 serves to supply the air conditioned by the air conditioning system 2 into the flow duct 8, the air being along a flow direction FR by means of the flow duct 8 via its lateral flows. opening S6 and S7 is led to the flow openings S1 to S5 opening into the vehicle interior.

As shown in FIG. 1, the component 4 is arranged centrally on the air conditioning system 2. That the component 4 has a curved course for accommodating the air conditioning system 2, the air conditioning system 2 being connected in the centrally arranged curvature, so that the flow channel 8 has laterally extending flow arms which open into lateral flow openings S5 and S4, in particular side nozzles, e.g. for ventilation of the side windows.

In order to enlarge the mixing space in the mixing device or mixing chamber for air that is as well-tempered as possible, it is provided that the flap for air distribution usually arranged there is omitted. For a possible space-saving arrangement of a flow control device 12 which effects the air distribution, this is in a transition area between two flow openings S1 to S7, e.g. arranged between the lateral flow opening S7 and the central flow opening S2. In other words, the flow control device 12 is integrated in the flow duct 8, in particular in the connection area of the component 4 to the air conditioning system 2 between the relevant flow openings S2, S7 and S8. Thus, the installation space already available in component 4 is used as a movement space for controlling the air distribution. This enables a simple displacement of the conventional ventilation flap of the mixing chamber into the connection area of air conditioning system 2 and component 4 with flow channel 8.

FIG. 2 schematically shows an alternative embodiment of a device 1 for air conditioning with an alternative embodiment for component 4. Instead of a large central flow opening S2 for the front area of the vehicle interior, two central flow openings Solutions S2 are provided, in each of which a flow control device 12 for air distribution for the flow channel 8 is arranged in the side arms. The respective flow control device 12 is arranged in each case in the transition region of the relevant flow openings S2 and S7 or S2 and S6, so that an air distribution is effected in the lateral arms of the flow channel 8 along the flow direction FR.

FIGS. 3 to 5 schematically show a cross section through a device 1 in the connection area of air conditioning system 2 and component 4 with different embodiments for a flow control device 12 arranged in the connection area.

FIG. 3 shows a flow control device 12 integrated in the flow channel 8, which is designed as a so-called V-cap and by means of which the flow rate of the air is controlled in the direction of the flow opening S7 and S2. Depending on the type and design of the flow channel 8, it can be polygonal in cross-section, in particular square or circular.

The flow control device 12 comprises an axis of rotation D about which two deflection elements 14a and 14b are arranged so as to be pivotable. The axis of rotation D of the flow control device 12 runs perpendicular to the flow opening S7 or S2 and to the flow direction FR. The axis of rotation D is arranged largely centrally in the flow channel 8 in a transition area between the two flow openings S7 and S2.

The deflection elements 14a, 14b each have a surface which is in the

Essentially corresponds to the cross-sectional area of the associated flow opening S7 or S2. In FIG. 3, different opening or closing states of the deflection elements 14a, 14b are partially or completely Open or close the relevant flow opening S7 or S2 shown.

FIG. 4 shows an alternative form of the flow control device 12 with an alternative form of the deflection element 14a, which has a slightly nodded form. The structure, the arrangement and the shape of the flow control device 12 are essentially determined by the predetermined air distribution in the relevant area of the flow channel 8. For example, the respective deflection element 14a and / or 14b can be designed with a spoiler or another flap shape.

FIG. 5 shows the flow control device 12 according to FIG. 4 with an associated partition 16, which prevents the air from flowing back into the flow opening S8 and thus in the direction of the air conditioning system 2. The partition 16 can be stationary or movable. The length I of the partition 16 is limited by a bearing belonging to the flow control device 12. FIG. 5 shows two partition walls 16 of different lengths. The partition 16 can alternatively be designed as a single flap.

FIGS. 6 to 13 schematically show a cross section through the component 4 in the transition area between two of the flow openings S1 to S8 with different embodiments for a flow control device 12 arranged there.

FIG. 6 shows a flow control device 12, the axis of rotation D of which runs horizontally to the relevant flow opening S2. The flow control device 12 has flap-like deflection elements 14a, 14b for opening and / or closing the flow openings S7 or S2. The position of the deflection elements 14a, 14b is set via a drive unit 18. FIG. 7 shows a further embodiment for a flow control device 12 for controlling the flow rate of a fluid medium, in particular air, through the flow channel 8 in the direction of the flow openings S7 and S2. The deflection elements 14a, 14b are mounted in the center and can be moved by means of the drive unit 18 between a position completely closing the flow opening S7 or S2 in question and a fully opening position.

FIG. 8 shows a further embodiment for a flow control device 12, which is designed as a double flap or blind. The two flaps of the double flap are driven by the drive unit 18 to adjust the deflection elements 14a, 14b via a common drive axis 20.

FIG. 9 shows, as a flow control device 12, a barn door flap which is formed from two flaps and is likewise connected to the drive unit 18 via a common drive axis 20.

FIG. 10 shows as a flow control device 12 a one-sided flap, which is also connected to the drive unit 18. FIG. 11 shows a further embodiment for a flow control device 12 - a so-called roller flap, which is arranged in the center of the flow channel 8 and whose flap or deflection elements 14a, 14b are changed in their position by means of a roller. FIGS. 12 and 13 show further alternative embodiments for a flow control device 12, on the one hand a butterfly flap and on the other hand a swing flap.

All of the flow control devices 12 described here can be prefabricated as a separate module, which can also be subsequently integrated into the component 4 in a particularly simple manner. Depending on the type and shape as well as the design of the flow control device 12, the deflection elements 14a, 14b are coupled or can be controlled or moved separately from one another. The deflection elements 14a, 14b can also be moved symmetrically and / or asymmetrically relative to one another.

By appropriate positioning of the deflection elements 14a, 14b, the flow control device 12 closes or opens the flow channel 8 into the relevant flow opening S1 to S8 at least partially or completely.

LIST OF REFERENCE NUMBERS

1 device for air conditioning 2 air conditioning 4 component 6 base body 8 flow channel 12 flow control device 14a, 14b deflection elements 16 partition 18 drive unit 20 drive axle

D axis of rotation E elements FR flow direction K plastic S1 to S8 flow openings

Claims

Patent claims

1. Component (4), in particular hybrid component for a device (1) for air conditioning a vehicle interior, comprising a metal base body (6) at least partially lined with plastic (K), the cavity of which forms a flow channel (8) for a medium flowing through and in which has at least one flow control device (12) integrated for controlling the flow rate of the medium.

2. Component according to claim 1, wherein the metallic base body (6) is provided with a plurality of flow openings (S1 to S8) for the entry and / or exit of the medium, which are arranged laterally, centrally, above and / or below.

3. Component according to claim 1 or 2, wherein the flow device (12) is arranged in a transition region between two flow openings (S2, S7).

4. Component according to claim 3, wherein the flow control device (12) between a central flow opening (S2) and a lateral flow opening (S7, S6) is arranged.

5. Component according to one of the preceding claims, wherein the axis of rotation (D) of the flow control device (12) extends perpendicular to the flow opening (S1 to S8).

6. Component according to one of the preceding claims, wherein the axis of rotation (D) of the flow control device (12) extends horizontally to the flow opening (S1 to S8).

7. Component according to one of the preceding claims, in which the flow control device (12) is designed as a control flap, in particular as a swing flap, a roller flap or a butterfly flap.

8. Component according to one of the preceding claims, in which the flow control device (12) is assigned at least one partition (16).

9. Component according to one of the preceding claims, in which the flow control device (12), in particular the control flap, comprises at least two deflection elements (14a, 14b) arranged about an axis of rotation (D), one of the deflection elements (14b) between a first one , the central flow opening (S2) completely closing position and a second position which completely opens the central flow opening (S2) is adjustably arranged and the other deflection element (14a) between a third position which completely closes the lateral flow opening (S7) and a fourth position, the lateral flow opening (S7) is completely adjustable.

10. The component according to claim 9, wherein the deflection elements (14a, 14b) are coupled or can be controlled separately from one another.

11. The component according to claim 9 or 10, wherein the deflection elements (14a, 14b) are movable relative to one another symmetrically and / or asymmetrically.

12. Component according to one of the preceding claims, in which the flow control device (12) is designed as a separate prefabricated module.

13. The device (1) for air conditioning a vehicle interior with an air conditioning system (2) and a component (4) connected to the air conditioning system (2) according to one of claims 1 to 12, wherein the component (4) is at least partially plastic (K ) lined metallic base body (6), the cavity of which forms a flow channel (8) for a medium flowing through, in particular air, and in which at least one flow control device (12) for controlling the flow rate of the medium is integrated.

14. The apparatus of claim 13, wherein the flow control device (12) is arranged in the component (4) in its connection area to the air conditioning system (2).

15. The apparatus of claim 13 or 14, wherein the component (4) is arranged centrally on the air conditioning system (2) and the flow channel (8) extends to the side and with a plurality of flow openings (S1 to S8) for entry and / or Is provided.

16. Device according to one of claims 13 to 15, wherein the flow control device (12) for controlling the air distribution between a central flow opening (S2), in particular a central nozzle, and a lateral flow opening (S6, S7), in particular a side nozzle, of the flow channel (8) is arranged.

17. Device according to one of claims 13 to 16, in which the flow control device (12) as a control flap, in particular one Butterfly flap, a swing flap or a roller flap is formed.

18. Device according to one of claims 13 to 17, wherein the flow control device (12) is designed as a separate prefabricated module.