FR3100585A1 - METHOD OF MANUFACTURING A VENTILATION DEVICE FOR A TANGENTIAL TURBOMACHINE AUTOMOTIVE VEHICLE COOLING MODULE - Google Patents

Abstract

A method of manufacturing a ventilation device for a motor vehicle cooling module, comprises providing an engine (33-1; 33-2) and an impeller (32-1; 32-2) , the injection molding of a frame (30; 78-1; 78-2) forming a housing (30-1, 30-2) adapted to receive the paddle wheel (32-1, 32-2), and the insertion of the impeller (32-1, 32-2) in the housing (30-1, 30-2) and the connection of the motor (33-1; 33-2) to the impeller (32 -1, 32-2) so that the rotation of the motor (33-1, 33-2) controls the rotation of the paddle wheel (32-1, 32-2). Figure for the abstract: Fig. 9

Description

METHOD FOR MANUFACTURING A VENTILATION DEVICE FOR A MOTOR VEHICLE COOLING MODULE WITH TANGENTIAL TURBOMACHINE

The invention relates to a method of manufacturing a ventilation device for a motor vehicle cooling module, with a tangential turbomachine. The invention also relates to a cooling module comprising a ventilation device manufactured by implementing such a manufacturing method.

Motor vehicles, whether combustion or electric, need to evacuate the calories generated by their operation and are therefore equipped with heat exchangers. A motor vehicle heat exchanger generally comprises tubes, in which a heat transfer fluid is intended to circulate, in particular a liquid such as water, and heat exchange elements connected to these tubes, often designated by the term " fins" or "spacers". The fins increase the exchange surface between the tubes and the ambient air.

However, in order to further increase the heat exchange between the heat transfer fluid and the ambient air, it is common for a ventilation device to be used in addition, to generate or increase a flow of air directed towards the tubes and the fins.

In known manner, such a ventilation device comprises a propeller fan.

The air flow generated by the blades of such a fan is turbulent, in particular due to the circular geometry of the propeller, and generally only reaches a part of the surface of the heat exchanger ( circular zone of the exchanger facing the fan blade). The heat exchange is therefore not homogeneous over the entire surface of the tubes and fins.

In addition, when switching on the fan is not necessary (typically when heat exchange with non-accelerated ambient air is sufficient to cool the heat transfer fluid circulating in the exchanger), the blades partially obstruct the flow of ambient air towards the tubes and the fins, which hinders the circulation of air towards the exchanger and thus limits the exchange of heat with the heat transfer fluid.

Such a fan is also relatively bulky, in particular because of the necessary dimensions of the propeller to obtain effective engine cooling, which makes it long and tricky to integrate it into a motor vehicle.

An object of the invention is to provide a method of manufacturing a cooling module for a motor vehicle that does not have at least some of the aforementioned drawbacks.

To this end, the subject of the invention is a method of manufacturing a ventilation device for a motor vehicle cooling module, comprising:
i) the supply of at least one motor and at least one paddle wheel;
ii) the injection molding of at least one frame forming at least one housing capable of receiving the at least one bladed wheel; And
iii) inserting the at least one impeller into the housing and connecting the motor to the at least one impeller such that rotation of the motor controls rotation of the at least one impeller.

Thus, advantageously, the method according to the invention allows rapid and reliable manufacture of a ventilation device for a cooling module.

Preferably, the method comprises one or more of the following characteristics, taken alone or in combination:
- In step ii) molding two frames each forming a housing;
- The two frames are assembled to one another, for example, by screwing, riveting or clipping;
- step iii) is repeated for each frame before assembling together the two frames thus equipped;
- In step ii) molding a frame forming two housings each capable of receiving at least one impeller;
- In step i) two impellers are provided for a motor;
- a first of the two impellers is fixed to the associated motor before being inserted into the housing by a first lateral end of the housing, one of the first and the second impeller is provided with a bearing ring with a free end, and the second impeller is inserted through a second side end of the housing, until the bearing ring receives a free end of each of the first and second impellers;
- the method further comprises the injection molding of the at least one impeller;
- the method further comprises:
a) the provision of at least one shutter and one actuator;
b) mounting the at least one rotary flap on the frame, so that the actuator can selectively control the closing of an opening through the frame by rotation of the at least one flap;
- the at least one flap and, preferably, the actuator form a module adapted to be fixed on the frame;
- The at least one paddle wheel is pivotally mounted about a first axis, the at least one flap is pivotally mounted about a second axis, the first and second axes being parallel;
- The at least one paddle wheel is pivotally mounted around a first axis, the at least one flap is pivotally mounted around a second axis, the first and second axes being perpendicular;
- the frame is formed so as to define a first opening extending substantially along a first plane, the at least one flap being mounted on the frame so as to extend along a second plane, in a closed position of a second opening defined by the frame, the first and second planes being inclined relative to each other; And
- The method further comprises a step of fixing at least one protective grid on the frame, to limit or even prevent projections inside a housing.

According to another aspect, a cooling module is described Cooling module comprising a cooling device obtained by implementing a method according to any one of the preceding claims, and at least one heat exchanger received in a conduit, the device ventilation being adapted to create an air flow in the duct.

According to another aspect, a motor vehicle with an electric motor is proposed, comprising a bodywork, a bumper and a cooling module as described above, the bodywork defining at least one cooling bay arranged under the bumper, the cooling module being arranged facing the at least one cooling bay.

Other characteristics, details and advantages of the invention will appear on reading the detailed description below, and on analyzing the appended drawings, in which:

schematically represents the front part of a motor vehicle, seen from the side;

is a schematic perspective view of a cooling module which can be implemented in the motor vehicle of FIG. 1, the flaps of which have been removed;

is a side view of the cooling module of Figure 2;

is similar to Figure 2, whose flaps are in the closed position of an opening in the housing of the cooling module;

is an exploded view of a detail of the cooling module of Figures 2 to 4;

is an exploded view of another detail of the cooling module of Figures 2 to 4;

is a longitudinal sectional view of part of the cooling module of Figures 2 to 4;

is a sectional view of a component of the cooling module of Figures 2 to 4;

is an exploded view of a first example of a ventilation device that can be implemented in the cooling module of FIGS. 2 to 4;

is a flowchart indicating the steps of an example of the method of manufacturing the ventilation device illustrated in FIG. 9;

is an exploded view of a second example of a ventilation device that can be implemented in the cooling module of FIGS. 2 to 4; And

is a flowchart showing the steps of an exemplary manufacturing process for the ventilator shown in Figure 11.

Description of embodiments

In the rest of the description, identical elements or identical functions bear the same reference sign. For the sake of conciseness of this description, these elements are not described in detail in each embodiment. On the contrary, only the differences between the variant embodiments are described in detail.

FIG. 1 schematically illustrates the front part of a motor vehicle 10 with a motor 12. The vehicle 10 comprises in particular a body 14 and a bumper 16 carried by a frame (not shown) of the motor vehicle 10. The body 14 defines a cooling bay 18, that is to say an opening through the bodywork 14. The cooling bay 18 can be unique as in the example illustrated. Alternatively however, body 14 may define a plurality of cooling bays. Here, the cooling bay 18 is located in the lower part of the front face 14a of the bodywork 14. In the example illustrated, the cooling bay 18 is located under the bumper 16. A grid 20 can be arranged in the cooling bay 18 to prevent projectiles from passing through the cooling bay 18. A cooling module 22 is arranged opposite the cooling bay 18. The grid 20 makes it possible in particular to protect this cooling module 22.

The cooling module 22 is more clearly visible in Figures 2 to 4.

The cooling module 22 comprises a ventilation device 24 associated with at least one heat exchanger 26.

As can be seen from the figures, the ventilation device 24 comprises at least one tangential fan, or more generally a tangential turbomachine, which draws in a flow of air in contact with heat or heat exchangers 26. In the example illustrated, the cooling module 24 comprises two tangential turbomachines 28-1, 28-2, detailed below.

As illustrated, the cooling module 22 essentially comprises a casing or frame 30 forming an internal air channel. The heat exchanger(s) 26 are arranged in the internal channel. Frame 30 accommodates at least one tangential turbomachine 28-1, 28-2. A rear part of the frame 30 forms a housing 30-1, 30-2 for receiving a tangential turbomachine 28-1, 28-2, in particular here the volute 30-1, 30-2 of a tangential turbomachine 28-1 , 28-2.

Each tangential turbomachine 28-1, 28-2 includes a rotor 32-1, 32-2. The rotor here consists of a 32-1, 32-2 turbine, more precisely of a tangential propeller or paddle wheel. Each turbine 32-1, 32-2 has a cylindrical shape. Each turbine 32-1, 32-2 advantageously comprises several stages of blades (or blades). Each turbine 32-1, 32-2 is rotatably mounted around an associated axis of rotation A32-1, A32-2. Each turbine 32-1, 32-2 is driven in rotation by an associated motor 33-1, 33-2.

In FIG. 2, all of the heat exchangers 26 delimit a surface S, called the work surface, one section of which is substantially rectangular in a plane (Y, Z).

Preferably, the Y direction corresponds to a horizontal direction, preferably also transverse, while the Z direction corresponds to a vertical direction, when the module is installed in the motor vehicle.

The surface S is delimited by two opposite end edges 38, 39 extending along direction Y, called length, and by two other opposite end edges 40, 41, along direction Z, called height.

The surface S corresponds to the rectangle defined by the exchanger 26, or if several exchangers are present, by the largest heat exchanger. However, it is also possible to juxtapose several heat exchangers vertically and/or horizontally, in which case the height of the surface S is the sum of the heights of the heat exchangers juxtaposed vertically (overlapping), and the length of the surface S is the sum of the lengths of the horizontally juxtaposed exchangers.

The first and second turbomachines 28-1, 28-2 are mounted parallel to each other, that is to say that the flow of air F1 ejected from the first turbine 32-1 of the first turbomachine 28 -1 is distinct from the airflow F2 ejected from the second turbine 32-2 of the second turbomachine 28-2. In other words, the air flow F1 ejected from the first turbine 32-1 does not cross the second turbine 32-2 and vice versa.

In the figures, the axes of rotation A32-1, A32-2 are parallel to the direction Y. The two turbines 32-1, 32-2 are thus mounted horizontally, in this case in a transverse direction. Alternatively, the axes of rotation A32-1, A32-2 can be vertical, i.e. parallel to the Z axis.

As also visible in the figures, the volute 30-1 of the first turbine engine 28-1 comprises a first portion 44-1 for guiding air around the first turbine engine 32-1 as far as a first outlet 46-1 of the air out of the cooling module 22. In known manner, the first air guide portion 44-1 advantageously comprises a wall in the form of a truncated spiral.

Similarly, the volute 30-2 of the second turbine engine 28-2 comprises a second portion 44-2 for guiding air around the second turbine engine 32-2 until the air exits from the cooling module. 22, referenced 46-2. The second guide portion 44-2 advantageously comprises a wall in the form of a truncated spiral.

According to the illustrated embodiment, the two outputs 46-1, 46-2 are arranged facing each other, oriented substantially in the same direction. This makes it possible to reduce the acoustic waves generated by the cooling module 22, compared to a configuration where the two outputs face each other and are oriented in opposite directions.

The illustrated configuration ensures that the air distribution of a first air flow F1 from the first turbine engine 28-1 via the first associated outlet 46-1 is substantially the same and in particular in the same direction as the distribution of a second airflow F2 from the second turbomachine 28-2 via the associated second outlet 46-2. In this case, the first and second airflows F1 and F2 are substantially vertical, and oriented downwards.

Thus, when the vehicle is in a humid or even wet environment, such as in the event of rain or fording, the turbomachine 28-1, 28-2 is protected, since water cannot be stored in the volute 30 -1, 30-2 but on the contrary is evacuated by output 46-1, 46-2. Therefore, any submersion of the cooling module 22 is avoided.

Advantageously, a grid (not shown in the figures) is attached to each of the outputs 46-1, 46-2. Such a grid can in particular make it possible to prevent projections from penetrating into the housing receiving the turbine 32-1, 32-2 and damaging this turbine 32-1, 32-2.

As also emerges from the figures, the axis of rotation A32-1 of the first turbomachine 28-1 is arranged substantially opposite the upper longitudinal edge 38 of the surface S and the axis of rotation A32-2 of the second turbomachine 28 -2 is arranged in the middle of the height of the surface S.

Nevertheless, depending on the configuration of the heat exchangers and/or the cooling power required for each exchanger, it is possible to position the turbomachines 28-1, 28-2 so as to dedicate them to the respective exchangers 26. Other relative positions of turbomachines 28-1, 28-2 are also possible.

Advantageously, the axis of rotation A32-2 of the second turbomachine 28-2 is arranged in a zone comprised between one fifth and four fifths of the height, preferably between one third and two thirds of said height, of the work surface S.

As illustrated in Figures 3 and 4, the module 22 is provided with air guide means 50-1, 50-2 associated with each turbine engine 28-1, 28-2 (these means are removed in Figure 2 at the end visibility of the interchange 26).

Each air guide means 50-1, 50-2 comprises at least one flap 52-1, 52-2, here a plurality of flaps 52-1, 52-2. Each flap 52-1, 52-2 is pivotally mounted between a closed position, illustrated in FIG. 4, in which the flaps 52-1, 52-2 close off a respective opening 51-1, 51-2 formed by the frame 30 of the cooling module 22, and at least one open position, in which the flaps 52-1, 52-2 allow at least part of the air flow to pass through the opening 51-1, 51-2 associated. In the closed position of the flaps 52-1, 52-2, these make it possible to direct the flow of air created towards the associated turbomachine 28-1, 28-2. On the contrary, an open position of the flaps 52-1, 52-2, generally reached when the associated turbine engine 28-1, 28-2 is off, makes it possible to direct at least part of the air flow created for example by the speed of the vehicle on which the cooling module 22 is mounted, through a respective opening 51-1, 51-2 in the frame 30, without passing through the associated turbomachine 28-1, 28-2.

The open position is particularly advantageous when the vehicle is traveling at high speed, in which case it is possible to put the turbomachines 28-1, 28-2 at a standstill.

The number of flaps 52-1 associated with the first turbomachine 28-1 can be identical to or on the contrary different from the number of flaps 52-2 associated with the second turbomachine 28-2, depending on the respective position of the turbomachines 28-1, 28- 2, in particular.

Each plurality of flaps 52-1, 52-2 is associated with a respective actuator 54-1, 54-2. An actuator 54-1 is described in more detail below, with reference to Figures 5 and 6, it being understood that the actuator 54-2 may be identical.

As illustrated in Figures 5 and 6, the actuator 54-1 firstly comprises an electric motor 56-1 whose output shaft rotates a first flap 52-1. The actuator 52-1 also comprises a connecting rod 58-1, the connecting rod 58-1 connecting together the first flap 52-1, driven in rotation by the output shaft of the electric motor 56-1, to the other flaps 52-1 of the plurality of flaps 52-1, such that the rotation of the first flap 52-1 is transmitted to the other flaps 52-1 of the plurality of flaps 52-1.

More specifically, each flap 52-1 comprises, at a first end, a cam 60-1. The axis of each cam 60-1 corresponds to the rotation axis A52-1 of the associated flap 52-1. The cams 60-1 associated with the various flaps 52-1 are connected together by the connecting rod 58-1. For example, connecting rod 58-1 includes a lug associated with each cam 60-1, received in a complementary housing formed in cam 60-1, such that the lug received in the housing can pivot relative to cam 60 -1. The cam 60-1 associated with the first flap 52-1 is driven in rotation by the output shaft of the electric motor 56-1, either directly or via a reduction gear. The attachment point of connecting rod 58-1 on each cam 60-1 is offset from axis A52-1 of rotation of associated flap 52-1.

As seen in Figure 5 in particular, the end opposite the cam 60-1 of each flap 52-1 here has a stud 62-1 received in a complementary housing 64-1 formed on a first upright 66-1 of the actuator 54-1. The first upright 66-1 here forms part of the housing 30 of the cooling module 22. The stud 62-1 and the complementary housing 64-1 are for example cylindrical, of circular section.

The cams 60-1 are also received in complementary housings, to guide their rotation around the axis A52-1 of rotation of the associated flap 52-1. The housings are formed in a second upright 68-1. The second upright 68-1 here forms part of the housing 30 of the cooling module 22.

As schematically illustrated in Figure 6, depending on the direction of rotation of the motor 56-1, rotation F3, F4 of the first flap 52-1 is caused around its longitudinal axis A52-1. The rotation F3, F4 of this first flap 52-1 causes the rotation of the associated cam 60-1, which in turn generates the displacement F5, F6 of the connecting rod 58-1. The displacement F5, F6 of the connecting rod 58-1 causes the rotation of the other cams 60-1 and, consequently, of the other flaps 52-1 of the plurality of flaps 52-1.

In order to improve the seal between the flaps 52-1 in the closed position, a gasket – not shown in the figures – can be molded onto the flaps. Alternatively or additionally, each flap 52-1 has a rib 70-1 along a first longitudinal side and a groove 72-1 of complementary shape to the rib 70-1, along a second longitudinal side, such that the rib of a first flap 52-1 is received in the groove of a second adjacent flap in the closed position of the flaps.

As illustrated in particular in Figure 8, each flap 52-1 can be tubular. Preferably, the face of a flap 52-1 intended to be oriented towards the heat exchangers 26 is substantially flat. The flat faces of the flaps 52-1 are aligned in the closed position of the flaps 52-1. A substantially flat surface is thus formed, which guides the flow of air towards the associated turbomachine 28-1, 28-2, by limiting the pressure drops of the flow of air thus guided. The opposite face of the flaps 52-1 is preferably curved.

Furthermore, FIGS. 7 and 8 also illustrate that each flap 52-1, 52-2 can be pivoted over an angular range of amplitude 110°, preferably of amplitude 102.5°. One of the two extreme positions of the flaps 52-1 here corresponds to the closed position of the flaps 52-1, in which the plane faces of the aligned flaps 52-1 form an angle α of between 5° and 20°, preferably substantially equal to 12.5° with an air inlet surface S2 normal to the air flow at the inlet of the ventilation device 24. The other of the two extreme positions of the flaps 52-1 corresponds to a position of the flaps in which the planar surfaces of the flaps 52-1 extend substantially horizontally. In this position, the resistance of the flaps 52-1, 52-2 to the flow of air passing through the associated opening 51-1, 51-2 is minimized.

Figure 9 illustrates a first example of ventilation device 24 that can be manufactured by implementing the method 100 illustrated in Figure 10.

According to this method 100, a first and a second motor 33-1, 33-2 are provided at a step 102. Also provided at this step 102 are four identical impellers 32-1a, 32-1b, 32-2a, 32-2b. The four impellers 32-1a, 32-1b, 32-2a, 32-2b can in particular be manufactured by injection molding. The four impellers 32-1a, 32-1b, 32-2a, 32-2b are for example made of plastic material, in particular of plastic material loaded with glass fibers. In this case, the four paddle wheels 32-1a, 32-1b, 32-2a, 32-2b are made of polyamide filled with glass fibers. The four impellers 32-1a, 32-1b, 32-2a, 32-2b can be associated two by two to form the two impellers 32-1, 32-2 implemented in the ventilation device 24.

At a step 104, a frame 30 is provided. Here, the frame 30 forms two housings 30-1, 30-2 for receiving a respective paddle wheel 32-1, 32-2. The frame 30 is for example made by injection molding. The frame 30 is for example made of plastic material, in particular of plastic material filled with glass fibers. Here, the frame 30 is made of polypropylene filled with glass fibers.

At a step 106, a first paddle wheel 32-1b, 32-2b is here connected directly to an associated motor 33-1, 33-2. The first paddle wheel 32-1b, 32-2b connected to the motor 33-1, 33-2 is then inserted into the associated housing 30-1, 30-2, via a first lateral end. We can then fix the motor 33-1, 33-2 on the frame 30. The motor 33-1, 33-2 then blocks the side end of the housing 30-1, 30-2 through which the first wheels were introduced. paddles 32-1b, 32-2b. Each second paddle wheel 32-1a, 32-2a which has not yet been introduced into the housing 30-1, 30-2 is then equipped, at each of its two ends, with a bearing ring 74. Each second bladed wheel 32-1a, 32-2a thus equipped is then inserted into the housing 30-1, 30-2, by a second lateral end, opposite to the first lateral end, until the bearing ring 74 mounted at the distal end of the second impeller 32-1a, 32-2a receives the distal end of the first impeller 32-1b, 32-2b. Advantageously, the housing 30-1, 30-2 forms a passage adapted to receive a rolling ring 74. It should be noted that a rolling ring 74 can alternatively be received in the housing 30-1, 30-2 before the insertion of the various paddle wheels 32-1a, 32-1b, 32-2a, 32-2b. Also according to another alternative, a bearing ring 74 is fixed on the free end of the first bladed wheel 32-1b, 32-2b connected to the motor 33-1, 33-2, before being inserted into the housing 30-1, 30-2.

The housing 30-1, 30-2 can then be closed, for example using a cover 76, during a step 108.

It is also possible to provide, during a step 110, means for guiding the air flow 50-1, 50-2 as described previously. In particular, it is possible to provide at this stage at least one flap 52-1, 52-2 and an associated actuator 54-1, 54-2.

In step 112, the rotary shutter or shutters 52-1, 52-2 are then mounted on the frame 30, and the associated actuator 54-1, 54-2 is adapted, so that the actuator 54-1 , 54-2 can selectively control the closing of the opening 51-1, 51-2 in the frame 30, by rotation of the flap or flaps 52-1, 52-2. As can be seen in FIG. 9, advantageously, the flap or flaps 52-1, 52-2, on the one hand, and the associated actuator 54-1, 54-2, on the other hand, advantageously form a module which can be manipulated in one piece. In particular, this module can be fixed on the frame 30 previously molded by injection.

During a step 114, a grid (not shown) can be fixed at the level of the outputs 46-1, 46-2 of the turbomachines 28-1, 28-2.

It should be noted that the order of the steps indicated above is given as an example. A person skilled in the art understands that this order is likely to be different. Those skilled in the art also understand that steps can be divided, a step of the method described above being able to be carried out between a first and a second part of another step.

Figure 11 illustrates a second example of ventilation device 24, which can be manufactured by implementing the method 200 illustrated in Figure 12.

The method 200 differs from the method 100 illustrated in FIG. 10 essentially in that the step 104 of supplying the frame 30 of the ventilation device 22 is here divided into two sub-steps. During a first sub-step 202, two frames 78-1, 78-2 are molded each forming a housing 30-1, 30-2 for receiving a paddle wheel 32-1, 32-2. Each frame 78-1, 78-2 also here defines an opening 51-1, 51-2. Then, during a step 204, the two frames 78-1, 78-2 are fixed together to thus form the frame 30 of the ventilation device 22. The two frames 78-1, 78-2 can in particular be fixed together by screwing, riveting, or clipping.

According to the example illustrated, the method 200 then continues substantially like the method 100 of FIG. 10. Alternatively, however, each frame 78-1, 78-2 is equipped separately with the turbomachine 28-1, 28-2 and/or with the air guiding means 50-1, 50-2, before the frames 78-1, 78-2 are fixed together to form the frame 30 of the ventilation device 22.

The invention is not limited to the examples described above. On the contrary, the invention is susceptible to numerous variants accessible to those skilled in the art.

In particular, in the examples illustrated, the ventilation device comprises two turbomachines. Alternatively, the ventilation device may comprise a single turbomachine or more than two turbomachines.

Also, in the examples shown, the flaps pivot around an axis parallel to the axis of rotation of the turbomachines. Alternatively, however, the flap(s) may pivot around an axis perpendicular to the axis of rotation of the turbomachine(s).

The paddle wheels can also each be one-piece.

Claims (15)

Method of manufacturing a ventilation device for a motor vehicle cooling module, comprising:
i) providing at least one motor (33-1; 33-2) and at least one impeller (32-1; 32-2);
ii) the injection molding of at least one frame (30; 78-1; 78-2) forming at least one housing (30-1, 30-2) capable of receiving the at least one paddle wheel (32- 1, 32-2); And
iii) inserting the at least one paddle wheel (32-1, 32-2) into the housing (30-1, 30-2) and connecting the motor (33-1; 33-2) to the at least one impeller (32-1, 32-2) such that rotation of the motor (33-1, 33-2) controls rotation of the at least one impeller (32-1, 32-2 ). Manufacturing process according to claim 1, in which in step ii) two frames (78-1, 78-2) each forming a housing (30-1, 30-2) are molded. Method according to Claim 2, in which the two frames (78-1, 78-2) are assembled together, for example by screwing, riveting or clipping. Method according to claim 2 or 3, in which step iii) is repeated for each frame (78-1, 78-2) before assembling together the two frames (78-1, 78-2) thus equipped. Manufacturing process according to claim 1, in which in step ii) a frame (30) is molded forming two housings (30-1, 30-2) each capable of receiving at least one bladed wheel (32-1, 32-2). A method according to any of claims 1 to 5, wherein in step i) two paddle wheels (32-1a, 32-1b; 32-2a, 32-2b) are provided for one motor (33-1 , 33-2). A method according to claim 6, wherein a first (32-1b, 32-2b) of the two paddle wheels (32-1a, 32-1b; 32-2a, 32-2b) is attached to the motor (33-1, 33-2) associated before being inserted into the housing (30-1, 30-2) by a first lateral end of the housing (30-1, 30-2), one of the first and the second wheel to blades (32-1a, 32-1b; 32-2a, 32-2b) is provided with a bearing ring (74) at a free end, and the second blade wheel (32-1a, 32-2a) is inserted through a second side end of the housing (30-1, 30-2), until the bearing ring (74) receives a free end of each of the first and second impellers (32-1a , 32-1b; 32-2a, 32-2b). A method according to any preceding claim, further comprising injection molding the at least one impeller (32-1, 32-2, 32-1a, 32-1b; 32-2a, 32-2b) . A method according to any preceding claim, further comprising:
a) providing at least one flap (52-1, 52-2) and an actuator (54-1, 54-2);
b) mounting the at least one rotary shutter (52-1, 52-2) on the frame (30), so that the actuator (54-1, 54-2) can selectively control the closing of a opening (51-1, 51-2) through the frame (30) by rotation of the at least one flap (52-1, 52-2). Method according to Claim 9, in which the at least one flap (52-1, 52-2) and, preferably, the actuator (54-1, 54-2) form a module adapted to be fixed to the frame. Method according to Claim 9 or 10, in which the at least one paddle wheel (32-1, 32-1) is pivotally mounted around a first axis (A32-1, A32-2), the at least one flap (52-1, 52-2) is pivotally mounted around a second axis (A52-1), the first (A32-1, A32-2) and second axes (A52-1) being parallel. Method according to Claim 9 or 10, in which the at least one paddle wheel (32-1, 32-1) is pivotally mounted around a first axis (A32-1, A32-2), the at least one flap (52-1, 52-2) is pivotally mounted around a second axis (A52-1), the first (A32-1, A32-2) and second axes (A52-1) being perpendicular. Method according to one of Claims 9 to 12, in which the frame (30) is formed so as to define a first opening (S2) extending substantially along a first plane, the at least one flap (52-1) being mounted on the frame (30) so as to extend along a second plane, in a closed position of a second opening (51-1, 51-2) defined by the frame (30), the first and second plane being tilted relative to each other. Method according to any one of the preceding claims, further comprising a step of fixing at least one protective grid to the frame (30), to limit or even prevent projections inside a housing (30-1 , 30-2). Cooling module (22) comprising a cooling device (24) obtained by implementing a method according to any one of the preceding claims, and at least one heat exchanger (26) received in a duct, the ventilation device ( 24) being adapted to create an air flow in the duct.