DE19546040A1 - Power regulation system for electric motor driving centrifugal blower for heating or ventilation system in motor vehicle - Google Patents

Abstract

The power of an electric motor (16) that is used to drive the turbine rotor (14) of a centrifugal blower is controlled by an electronic circuit having power transistors that have to be cooled. The transistors (48) are mounted on a heat sink of aluminium (42) positioned at the rear of the motor. The turbine rotates within an involute-shaped casing (22) and this has a side channel (10) with a passage (66) leading to the region where the power transistors and heat sink are located. The air is directed across the heat sink and this has a series of fins to dissipate the heat.

Description

The invention relates to a power control device for an electric motor consisting of a plate, whose first surface is at least one electronic building element carries and its second surface with cooling fins is provided, which overflows with an air stream will.

Such a device generally comprises several electronic components, in particular power transistors leading to an electronic circuit belong to the regulation of the engine. These components give off a significant amount of heat by the Airflow is radiated over the cooling fins flows, which thus form the fins of a radiator.

In a special application, this is done Set up the regulation of an electric motor Blower leading to a heating and / or air conditioning system can belong to motor vehicles, such as this as set out in FR-A-2 676 610.

The blower generates a blower airflow from which  a small part is branched off to one on the Cooling fins of the device directed air flow deliver.

The known power control devices lead not completely satisfactory results because either the cooling fins are not of a suitable shape or the air flow takes a complicated course must to bring about the cooling.

This is particularly the case with the power controller aforementioned publication the case in which the Cooling fins have a circular arc shape that are not sufficient to ensure efficient heat dissipation Act.

The main purpose of the invention is that to eliminate the aforementioned disadvantages.

To do this, she proposes a power regulator device from initially defined type in which the cooling fins are arranged so that an inlet line to which the Airflow can be supplied, and two outlet strands are formed that are connected to the inlet strand are connected and can discharge the air flow, so that the airflow along a Y-shaped path circulated tangentially to the plate.

The air circulation is thus tangential to Plate according to a course in three Y-shaped arranged strands in three main directions, whereby bring about an optimal overflow of the plate leaves.

In a preferred embodiment of the invention the inlet duct includes one near an edge the inlet end of the plate and an outlet end that is arranged in a central region of the plate is, while each exhaust line is one in that mean  area arranged inlet end and a nearby includes an outlet end located at one edge of the plate, so that the inlet line and the two outlet strands in radial directions relative to this Extend middle area.

This allows the airflow from a plate edge flow over the plate and into the inlet line step to get to the middle of the plate, whereupon it is distributed between the exhaust lines to reach two other edges of the plate.

The outlet strands advantageously extend one in a general direction, one 45 ° angle in relation to the general direction of the inlet line forms.

In one embodiment of the invention, the Cooling fins in the central area of the plate a smaller one Height to a receptacle for inserting one end of the engine.

The plate advantageously carries at least three electronic power components, in particular Transistors, each on the inlet branch or the side opposite the two outlet lines are arranged. This makes every strand of cooling assigned a special electronic component net.

According to another characteristic, the exhaust lines have appropriate cross sections, which is a uniform Distribution of airflow between the two outlets allows strands.

From another point of view concerns the inven a centrifugal blower in the version with a turbine housed in a spiral casing of an housing under the influence of an electric motor  can rotate, with an in the installation housing direction of the type defined above is installed.

This device is preferably in a bottom of the Built-in housing installed in a certain position, so that the plate extends in a plane that runs approximately perpendicular to the axis of rotation of the motor, and that the ribbed surface on the Side of the motor.

According to another characteristic, the one extends inlet line and the two outlet lines of the cooling fins each in a position that is approximately radial in Relationship to the axis of rotation of the motor is arranged '.

The inlet line is advantageously above a Air inlet with an overpressure area of the volute ses in connection while the two exhaust lines each through an air outlet with a vacuum area of the volute casing.

The air flow is therefore circulated through Natural circulation.

In a preferred embodiment of the invention the air inlet and the two air outlets each defined by a channel that a ver binding of the volute casing to the bottom of the installation manufactures housing. These three channels can be one in one piece with the bottom of the installation housing his.

In a centrifugal fan of the aforementioned type includes the volute housing - an outlet nozzle, the extends in a direction tangential to Turbine runs, the connection between the Outlet socket and the spiral housing a spout is trained.  

According to the invention it is provided that the inlet line the power control device an angle of about Forms 65 ° to 75 ° in relation to this spout.

This results in an optimal design for creating an overpressure area on Air inlet as well as negative pressure areas in the air omit.

In the Be spelling will refer to the accompanying drawings taken on which the following is shown.

- Fig. 1 shows a cross-sectional view of a Zen centrifugal blower, which is provided with a power control device according to the invention, wherein the sectional plane runs perpendicular to the axis of rotation of the motor and passes through the volute along the line I-I of Fig. 2 and wherein the motor and the Turbine have been omitted to simplify the drawing.

FIG. 2 shows a sectional view along the line II-II of FIG. 1.

- Fig. 3 shows a sectional view along the line III-III of Fig. 1.

- Fig. 4 shows a plan view of the power control device of the fan of Fig. 1st

- Fig. 5 is a sectional view taken along line VV of Fig. 4.

- Fig. 6 shows a bottom view of the device of FIG. 4.

The Zentrifugalge shown in FIGS. 1 to 3 blower comprises a component housing 10 with a helical or spiral-shaped part 12, which is hereinafter referred to as "spiral casing 12", inside which a turbine 14 under the action of an electric motor 16 by a Axis of rotation XX rotates ( Fig. 2 and 3).

The volute casing 12 has an end surface 18 with a circular opening 20 which is centered on the axis XX and serves for the inlet of the air into the interior of the volute casing 12 .

The latter also includes a side wall 22 which is defined by generatrixes arranged parallel to axis XX and which runs on a generally spiral curve. The wall 22 is open and, on the one hand, connects to a wall 24 via a grommet 26 and, on the other hand, to an opposite wall 28 which extends the wall 22 ( FIG. 1). The walls 24 and 28 together form an outlet or discharge nozzle 30 which extends in a direction which is generally tangential in relation to the turbine 14 . The nozzle 20 is also limited by the end surface 18 and an opposite end surface 32 .

In this way, air can be admitted through the opening 20 into the volute casing, set in motion by the turbine by means of centrifugal force and discharged from the volute casing through the outlet connection 30 .

At the end surface 32 is followed by a housing base 34 which has a bottom wall 36 and a stepped side wall 38 , which housing base serves as a measure for the motor 16 .

A power regulator device 40 according to the invention is also used in the housing base.

The device 40 comprises a plate 42 with an approximately rectangular shape, the plane of which is arranged perpendicular to the axis XX. The plate 42 consists of heat-conducting material, for example aluminum. It is fastened in the bottom of the installation housing 34 with a ring-shaped holder 39 and three screws 41 ( FIGS. 1, 2 and 3).

The plate 42 has a generally smooth first surface 44 which is arranged opposite the bottom wall 36 of the installation housing (FIGS . 2 and 3) and on which an electronic circuit for controlling the motor is attached. This electronic circuit contains in particular three power transistors 46 , 48 and 50 ( FIGS. 1, 4 and 6).

The plate 42 has an opposite surface 52 on which three rows of cooling fins 54 , 56 and 58 are formed ( FIGS. 1 and 4).

The cooling fins 54 run parallel to one another and to an axis E, which is held in the plane of the plate 42 and passes through its center O through which the axis XX runs. The ribs 54 form an inlet line 60 .

The cooling fins 56 run parallel to one another and to an axis S1, which is contained in the plane of the plate and passes through the center O. These ribs 56 form a first outlet line 62 .

The cooling fins 58 run parallel to one another and to an axis 52 which is contained in the plane of the plate and passes through the center O thereof. The ribs 56 form a second outlet line 64 .

As can be seen in Fig. 1, the axis E of the inlet strand is at an angle A of approximately 70 ° in relation to the connecting nozzle 26 of the outlet connector 30 .

In addition, axes S1 and S2 each form an angle of 45 ° in relation to axis E ( FIG. 1.

The ribs 54 of the inlet branch are branched off in a central region of the plate in order to form the ribs 56 of the outlet branch 62 on one side and the ribs 58 of the outlet branch 64 on the other side, so that the Y-shaped overall structure is created. The cooling fins can be overflowed by an air flow that comes through the inlet duct from the volute casing and is then discharged through the two outlet strands into the volute casing.

For this purpose, the housing base delimits three channels which connect the spiral housing to one of the three strands of the plate 42 .

These three channels initially comprise an inlet channel 66 , the first end of which leads into the volute casing, while the other end delimits an air opening 68 ( FIGS. 1 and 2). In addition, a first outlet channel 70 is formed in the installation housing, the first end of which leads into a vacuum region of the volute housing, while the other end delimits an air opening 72 ( FIG. 1). In addition, a second outlet channel 74 with a curved shape has an end which leads into a vacuum region of the volute, while its other end delimits an air opening 76 ( FIGS. 1 and 3).

The three channels 66 , 70 and 74 extend in directions that are generally parallel to axis XX ver. They can be carried out directly by integrally molding the housing base or attached to it.

The air openings 68 , 72 and 76 are each arranged in Rich direction of the axes E, S₁ and S₂ and relative to the strands 60 , 62 and 64 ( Fig. 1).

In this way, an air flow F is removed in an overpressure area of the volute casing and passed to the opening 68 . The air stream then flows along the cooling fins 54 of the inlet line 60 , whereupon it divides into two streams which flow along the cooling fins 56 and 58 of the two outlet lines 62 and 64, respectively. This air is then discharged through the openings 72 and 76 so that it passes through the outlet channels 70 and 74 back into the volute. This brings about the cooling of the components of the circuit, in particular the power transistors 46 , 48 and 50 . In order to achieve optimum efficiency, the transistors 46 , 48 and 50 are each arranged in the area of one strand. In the present example, the three transistors are arranged in the region of the inlet branch or in the region of the outlet branches.

Otherwise, the outlet strands 62 and 64 have corresponding outlet cross-sections in the region of the openings 72 and 76 in order to bring about a uniform distribution of the air flow between the two strands.

Referring now to Figs. 4 to 6 in order to describe in detail an inventive device 40, the guide plate 42 in an identical off as the plate described above comprises.

The inlet string 60 has an inlet end 78 proximate an edge 80 of the plate 42 and an outlet end 84 located in a central region 86 of the plate, i.e. around the center O. The outlet string 62 has an inlet end 88 located in this central region and an outlet end 90 near an edge 92 of the plate. Likewise, the outlet string 64 has an inlet end 94 located in the central region and an outlet end 96 near an edge 98 of the plate.

The strands 60 , 62 and 64 thus extend in directions which are generally radial in relation to this central region. As can be seen clearly in FIG. 5, the cooling fins have a lower height in the central region, so that this central region limits a generally frustoconical receptacle 100 for the insertion of one end of the motor 16 . This allows the axial installation space of the fan to be reduced, while at the same time ensuring efficient cooling of the power transistors.

As can be seen in FIG. 4, the transistors 46 , 48 and 50 are each fastened in the region of the strands 60 , 62 and 64 on the side opposite the cooling fins.

The plate 42 also includes three holes 102 , 104 and 106 for attachment to the bracket 39 .

In FIG. 5 for simplicity the intersections of the ribs with the frustoconical support 100 is not shown.

The regulator device according to the invention is natural not for use in a centrifugal fan to a heating and / or air conditioning system for motor vehicles limited witness.

It can also be used together with other types of electric motors be used.

Claims (12)

1. Power control device for an electric motor, consisting of a plate ( 42 ), the first surface ( 42 ) carries at least one electronic component ( 46 , 48 , 50 ) and the second surface ( 52 ) with cooling fins ( 54 , 56 , 58 ) is that can be overflowed by an air stream (F), characterized in that the cooling fins ( 54 , 56 , 58 ) are arranged so that an inlet line ( 60 ) to which the air stream (F) can be supplied, and two Outlet strands ( 62 , 64 ) are formed, which are connected to the inlet strand ( 60 ) and can derive the air flow (F), so that the air flow (F) circulates tangentially to the plate ( 42 ) along a Y-shaped path. 2. Device according to claim 1, characterized in that the inlet strand ( 60 ) comprises a near the edge ( 80 ) of the plate angeord netes inlet end ( 78 ) and an outlet end ( 84 ) which in a central region ( 86 ) Plate is arranged, while each outlet strand ( 62 ; 64 ) comprises an arranged in this central region inlet end ( 88 ; 94 ) and a near an edge ( 92 ; 98 ) of the plate angeord net outlet end ( 90 ; 96 ), so that the inlet branch and the two outlet branches extend in radial directions (E; S1; S2) in relation to the central region ( 86 ). 3. Device according to one of claims 1 and 2, characterized in that the outlet strands ( 62 , 64 ) each extend in a general direction (S1, S2) which is at an angle of 45 ° in relation to the general direction (E) the inlet strand ( 60 ) forms. 4. Device according to one of claims 2 and 3, characterized in that the cooling fins ( 54 , 56 , 58 ) in the central region ( 86 ) have a lower height to a receptacle ( 100 ) for the insertion of one end of the motor ( 16th ) to build. 5. Device according to one of claims 1 to 4, characterized in that the plate ( 42 ) carries at least three electronic power components ( 54 , 56 , 58 ), in particular transistors, each of which on the inlet branch ( 60 ) or the two outlet strands ( 62 , 64 ) are arranged opposite side. 6. Device according to one of claims 1 to 5, characterized in that the outlet strands ( 62 , 64 ) have corresponding cross sections. 7. Centrifugal fan with a turbine ( 14 ) which can rotate in a spiral housing ( 12 ) of a built-in housing ( 10 ) under the action of an electric motor ( 16 ), characterized in that the built-in housing ( 10 ) has a device ( 40 ) according to one of the Claims 1 to 6 records. 8. Centrifugal fan according to claim 7, characterized in that the device ( 40 ) in a bottom ( 34 ) of the mounting housing is installed in a certain position, so that the plate ( 42 ) extends in a plane which is approximately perpendicular to Axis (XX) of the motor ( 16 ) extends, and that the surface ( 52 ) provided with ribs ( 54 , 56 , 58 ) is on the side of the motor ( 16 ). 9. Centrifugal fan according to claim 8, characterized in that the inlet strand ( 60 ) and the two outlet strands ( 62 , 64 ) each extend in a position which is approximately radial in relation to the axis of rotation (XX) of the motor ( 16 ) is arranged. 10. Centrifugal blower according to one of claims 7 to 9, characterized in that the inlet line ( 60 ) via an air inlet ( 68 ) is connected to an overpressure region of the volute casing, while the two outlet lines ( 64 , 66 ) each have an air outlet ( 72 , 74 ) are connected to a negative pressure area of the volute casing. 11. Centrifugal fan according to claim 10, characterized in that the air inlet ( 68 ) and the two air outlets ( 72 , 74 ) are each defined by a channel ( 66 , 70 , 74 ) which connects the volute casing ( 12 ) to the floor ( 34 ) of the built-in housing. 12. A centrifugal fan according to claim 11, wherein the housing ( 2 ) comprises an outlet connection ( 30 ) which is connected by a grommet ( 26 ) to the spiral housing ( 12 ), characterized in that the inlet line ( 60 ) of the device ( 40 ) forms an angle of 65 ° to 75 ° in relation to the spout ( 26 ).