DE102014107021A1 - Automotive air conditioning system - Google Patents

Abstract

The present invention relates to an automotive air conditioning system having a housing (1, 8, 8 ') in which an air-conducting duct system (5, 6) is formed, and a fan (2) which is driven by a fan motor (4) and which for generating an air flow (H, K) in the air duct system (5) is arranged. The motor vehicle air conditioning system according to the invention further comprises a control unit (9) for controlling the fan motor (4), wherein the control unit (9) comprises a heat sink arrangement (10, 11) which is arranged in the air-conducting duct system (5, 6). In this case, the air-conveying duct system (5, 6) branches downstream of the blower (2) into a main duct (5) and a cooling duct (6) such that the main duct (5) distributes the air from the blower (2) to the air outlets the passenger compartment is formed and the cooling channel (6) for discharging a partial air flow (K) downstream of the fan (2) for cooling the fan motor (4) is formed. The motor vehicle air conditioning system according to the invention is characterized in that the control unit (9) is arranged in the air-conducting duct system (5, 6) such that the surface of the heat sink arrangement (10, 11) is arranged in the cooling duct (6).

Description

The present invention relates to an automotive air conditioning system. This generically includes a housing in which an air-conducting duct system is formed, and a fan which is driven by a fan motor and which is arranged to generate an air flow in the air-conducting duct system. Furthermore, the generic motor vehicle air conditioning system comprises a control unit for controlling the fan motor, wherein the control unit comprises a heat sink assembly, which is arranged in the air-conducting duct system. The air duct system thereby branches downstream of the fan into a main duct and a cooling duct such that the main duct for distributing the air from the blower to the air outlets of the passenger compartment is formed and the cooling duct is designed to divert a partial airflow downstream of the blower for cooling the blower motor ,

Such generic automotive air conditioning systems are for example from the US2008 / 0205501A1 known. The control unit has a heat sink, which is arranged with a plurality of cooling knobs below the impeller in the main channel, so that the waste heat of the control unit regularly discharged from the main air flow and thus the control unit can be cooled. In order to increase the cooling effect, the heat sink is carried out at right angles down into the cooling channel, where it is in heat-conducting contact with the fan motor and, alternatively, the cooling effect is further increased by additional cooling legs.

A disadvantage of this arrangement, however, that the use of standardized control units and their flexible arrangement in the air duct system are difficult. Furthermore, it is a perennial endeavor to keep the maximum noise through the air duct system as low as possible.

It is the object of the present invention to mitigate the abovementioned disadvantages and to allow in particular a flexible and low-noise arrangement of the control unit in the air-conducting duct system.

This object is achieved by an automotive air conditioning system according to claim 1. Advantageous training and further developments emerge from the dependent claims.

The motor vehicle air conditioning system according to the invention is characterized in that the control unit is arranged in the air-conducting duct system such that the surface of the heat sink arrangement is arranged in the cooling duct. The partial air flow, which is diverted from the main air flow into the cooling channel, thus flows past the heat sink assembly, whereby the control unit is cooled. The fact that the heat sink assembly is not in the main air flow, there is achieved a lower air turbulence and thus reduces the noise level.

It may be possible in this case to modify an existing arrangement with a cooling channel in that the heat sink arrangement previously oriented in the main channel now projects into the cooling channel by tilting the control unit through an angle between 90 ° or 180 °. For this purpose, only the channel walls must be adjusted accordingly. The rough division of the installation space and the channel guide is only slightly affected, especially if elongated, cuboid control units are used.

The heat sink arrangement can be configured as desired. In an advantageous embodiment, it comprises a multiplicity of pin cooling bodies, cooling knobs and / or cooling ribs which are aligned in the cooling channel. As a result, the heat exchange and thus the cooling effect is increased. The pin heatsink, cooling knobs and / or cooling fins are not in the main air flow and thus generate no vortex and associated noise.

Furthermore, the control unit with the heat sink arrangement can be arranged completely in the cooling channel. In this case, the electrical connection lines between the control unit and engine in the cooling channel can be laid. Alternatively, however, the control unit can also be arranged on the cooling channel wall in such a way that, for example, a side of the control unit facing away from the heat sink arrangement is inserted into an opening in the channel wall.

According to one embodiment, the cooling channel branches off from the main channel in an area in the vicinity of the blower and is returned directly to the blower motor. This is advantageous because then the control unit and the motor can be positioned close to each other. By such a compact arrangement, in particular the cable lengths between the engine and control unit can be kept low. This not only has an advantageous effect on the assembly and material costs, but also on the electromagnetic compatibility.

Alternatively or additionally, the heat sink may be arranged on a side opposite the fan motor side of the cooling channel. As a result, the air flow in the cooling channel is better utilized, which in turn has an advantageous effect on the dimensioning of the common cooling channel. It is also advantageous if the surface normal of the heat sink is aligned with the fan motor, because in this way the electromagnetic shield is further improved.

According to preferred embodiments of the invention, the fan is a radial fan. The cooling channel is then downstream with the internal volume of the impeller in fluid dynamic connection. As a result, the air flow in the cooling channel is further assisted by the suction from the radial fan, whereby the cooling effect is improved.

Typically, the fan may be disposed in a volute casing in which the main channel is passed through the free end of the coil. The cooling channel is then discharged next to the main channel and in the direction of rotation to the main channel. The direction of rotation here denotes the direction of rotation of the fan wheel during normal operation and also the rotational orientation of the spiral housing towards the free end of the spiral. The advantage of this arrangement of the channels is that the cooling channel is thus in the lee of the main channel and thus hardly affected. If appropriate, by the branch to the cooling channel resulting air vortexes are thus transported to a much lesser extent from the main air flow to the air outlets to the passenger compartment.

In a further embodiment of the invention, the fan motor is mounted in a motor mount, which extends plate-shaped substantially perpendicularly from the motor shaft. The control unit is then fixed with respect to the mounting position of the impeller on the underside of the plate-shaped extension of the motor mount. This simplifies the assembly.

Furthermore, it may be advantageously provided that at least part of the wall of the cooling channel itself is formed by the motor mount. For this purpose, a housing half shell can be attached to the underside of the motor mount, which is airtight connected to the motor mount. In this case, the cooling channel is in two pieces - possibly also in several pieces - executed and formed by assembly on the motor holder. Alternatively, the motor holder with the cooling channel can also be integrally formed.

The invention will now be explained in more detail with reference to an embodiment and with reference to the figures.

The 1 shows a perspective partial section of an automotive air conditioning system according to the embodiment of the invention,

the 2 schematically shows a sectional view in plan view of the motor vehicle air conditioner according to the embodiment of the invention and

the 3 and 4 schematically show further sectional views along in the 2 Plotted lines II and II-II.

In the 1 - 4 are cutouts and sectional views of an embodiment of the invention shown. It is a part of the air conditioning in the vicinity of the blower 2 shown. In the embodiment, it is a radial fan, in principle, other fans are used. The perspective part of the 1 is characterized by three each perpendicular to each other sectional views in the 2 to 4 added.

The air conditioning system includes a volute casing 1 , which is composed of several sections, of which the housing sections 1A - 1D are shown. The housing section 1A puts the immediate enclosure around the impeller 2 dar. The housing section 1B surrounds the free spiral end, which is used to distribute the air into the main channel 5 is provided. The main channel 5 is at its top through the housing section 1B limited and is to distribute the air from the blower 2 formed to the air outlets of the passenger compartment, as is known in the prior art (not shown). The location of the main canal 5 is further in the sectional views of 2 to 4 more precisely indicated.

Typically, further housing sections are provided to the main channel 5 equip according to the requirements of the air conditioning and to form a complete air duct system and this airtight to close (not shown). Housing sections can be connected to one another as single or multiple pieces or integrated with one another, ie, formed integrally with different housing sections.

The fan wheel 2 is on a motor shaft 3 stored and will - as in the 3 and 4 to see - from a blower motor 4 powered by a control unit 9 is controlled. The fan wheel 2 is designed so that it rotates in the direction of rotation of the spiral housing - in this case clockwise or rotational direction D -. This causes the air to spiral into the housing section 1B ie the main channel 5 promoted. In direction of rotation D to the main channel 5 is located in relation to the main channel 5 rear housing section 1C , which as an end face the blower 2 opposite, but of this through the housing section 1D is shielded. By doing housing section 1C is a passage opening 7 provided, through which the cooling channel 6 from the main channel 5 is dissipated. The more accurate course of the cooling channel 6 is particularly related to the 2 and 3 explained in more detail.

The main air flow H is through the rotating impeller 2 in the housing section 1A generated and in the free end of the spiral portion of the housing section 1B discharged. Like in the 2 illustrated, the cooling air flow K branches downstream of the fan 2 from. The cooling air flow K dips into the downwardly directed cooling channel 6 off to the blower motor 4 below the blower wheel 2 to cool.

According to the prior art, the control unit 9 with her heat sink 10 preferably arranged in the vicinity of the positioning region P, so that the heat sink 10 Heat can dissipate through the main air flow H heat of the control unit. However, because effective and available on the market heat sink typically via cooling fins, cooling knobs or cooling pins 11 have such a positioning of the heat sink 10 by its vortex formation and associated noise when passing the main air stream proved to be disadvantageous. In the following, another arrangement is proposed according to the embodiment.

In the 3 and 4 are sectional views according to the in the 2 drawn section lines II and II-II shown. The blower motor 4 with the motor shaft 3 is in a motor mount 8th stored. The fan wheel 2 is at the upper end of the motor shaft 3 arranged so that it passes through the blower motor 4 about the rotational axis D can be set in rotation. The engine mount 8th expands in one area 8th dish-shaped outwards, ie perpendicular to the motor shaft 3 , and forms the bottom for the beginning main air flow H.

The cooling air flow K branches from the main air flow H when entering the housing part 1B backwards through the passage opening 7 through and near the blower 2 in the cooling channel 6 initially led down. The cooling channel 6 then runs into an area below the fan 2 directly to the blower motor 4 and is returned from there back up.

The cooling air flow K can be maintained upright for two reasons: First, by the configuration of the housing section 1B and 1C near the porthole 7 , Here, a positive pressure situation can be generated locally, for example by the main air flow H laterally striking a channel which branches off a partial air flow and through the passage opening 7 passes. In addition, it is advantageously provided that the cooling channel 6 downstream with the internal volume of the impeller 2 is in fluid dynamic connection, so that an additional suction effect is achieved.

According to the invention, the control unit 9 arranged in the air duct system such that the heat sink 10 in the cooling channel 6 lies. The cooling pins 11 are doing directly into the cooling channel 6 aligned. According to the embodiment shown, the control unit is located 9 with the heat sink 10 and the cooling pins 11 completely in the cooling channel 6 where the engine attitude 8th . 8th in the vicinity of the positioning region P a part of the upper and side walls of the cooling channel 6 forms. The control unit 9 is in this case at the bottom of the plate-shaped extension 8th the engine mount 8th attached.

In the embodiment shown, the cooling pins 11 on a blower motor 4 opposite side of the cooling channel 6 arranged, wherein the surface normal of the heat sink 10 and thus the cooling pins 11 himself to the blower motor 4 is aligned (see 4 ). As a result, the cooling air flow K is utilized in its full width, which allows a more efficient utilization of the cooling capacity of the cooling air flow. Furthermore, the metallic surface of the heat sink acts 10 also shielding against electromagnetic radiation of the blower motor 4 ,

In this way, the control unit 9 as in the previously described prior art solution near the blower motor 4 to be ordered. The electrical wires 12 between the blower motor 4 and the control unit 9 can thus be made as short as possible, whereby the electromagnetic radiation can be kept low. On the other hand, such an arrangement also allows a simple re-design of an air conditioning system, which the control unit so far at the top of the motor mount 8th H provided in the main air flow.

LIST OF REFERENCE NUMBERS

1

volute

1A-1D

housing sections

2

Blower, blower wheel

3

motor shaft

4

blower motor

5

main channel

6

cooling channel

7

Port

8, 8 '

engine mount

9

control unit

10

heatsink

11

cooling pins

12

Electric lines

D

direction of rotation

H

Main air flow

K

Cooling air flow

P

positioning region

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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.

Cited patent literature

• US 2008/0205501 A1 [0002]

Claims (10)

Automotive air conditioning system comprising - a housing ( 1 . 8th . 8th ), in which an air-carrying duct system ( 5 . 6 ), - a blower ( 2 ), which by a blower motor ( 4 ) and which is used to generate an air flow (H, K) in the air-carrying duct system ( 5 ), - a control unit ( 9 ) for controlling the fan motor ( 4 ), the control unit ( 9 ) a heat sink assembly ( 10 . 11 ), which in the air duct system ( 5 . 6 ), wherein the air-carrying duct system ( 5 . 6 ) downstream of the fan ( 2 ) into a main channel ( 5 ) and a cooling channel ( 6 ) branches, that the main channel ( 5 ) for distributing the air from the fan ( 2 ) is formed to the air outlets of the passenger compartment and the cooling channel ( 6 ) for diverting a partial air flow (K) downstream of the fan ( 2 ) for cooling the fan motor ( 4 ), characterized in that - the control unit ( 9 ) in the air-conveying duct system ( 5 . 6 ) is arranged such that the surface of the heat sink assembly ( 10 . 11 ) in the cooling channel ( 6 ) is arranged. Motor vehicle air conditioning system according to claim 1, characterized in that the heat sink arrangement ( 10 . 11 ) a plurality of pin heatsinks ( 11 ), Cooling knobs and / or cooling fins, which in the cooling channel ( 6 ) are aligned. Automotive air conditioning system according to claim 1 or 2, characterized in that the control unit ( 9 ) with the heat sink assembly ( 10 . 11 ) completely in the cooling channel ( 6 ) is arranged. Motor vehicle air conditioning system according to one of claims 1 to 3, characterized in that the cooling channel ( 6 ) in an area near the fan ( 2 ) from the main channel ( 5 ) branches off and directly to the blower motor ( 4 ) is returned. Motor vehicle air conditioning system according to one of the preceding claims, characterized in that the heat sink ( 10 . 11 ) on a blower motor ( 4 ) opposite side of the cooling channel ( 6 ) is arranged. Motor vehicle air conditioning system according to claim 5, characterized in that the surface normal of the heat sink ( 10 ) to the blower motor ( 4 ) is aligned. Motor vehicle air conditioning system according to one of the preceding claims, characterized in that the blower ( 2 ) is a radial fan and the cooling channel ( 6 ) downstream with the internal volume of the impeller ( 2 ) is in fluid dynamic connection. Automotive air conditioning system according to one of the preceding claims, characterized in that - the blower ( 2 ) is arranged in a spiral housing, in which the main channel ( 5 ) through the free spiral end ( 1B ) and - the cooling channel ( 6 ) next to the main channel ( 5 ) and in the direction of rotation (D) to the main channel ( 5 ) is discharged. Automotive air conditioning system according to one of the preceding claims, characterized in that - the blower motor ( 4 ) in an engine mount ( 8th . 8th ) is mounted, which plate-shaped substantially perpendicularly from the motor shaft ( 3 ), and - the control unit ( 9 ) in relation to the mounting position of the impeller ( 2 ) at the bottom of the plate-shaped extension ( 8th ) of the engine mount ( 8th ) is attached. Motor vehicle air conditioning system according to one of the preceding claims, characterized in that at least part of the wall of the cooling channel ( 6 ) through the engine mount ( 8th . 8th ) is formed.

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