FR3057335A1 - CIRCUIT FOR EVENTING A CLOSED CAVITY OF AN ACTUATOR - Google Patents

Abstract

The present invention describes a venting circuit (1) of a closed cavity (2) of a fluid flow metering actuator (50), in particular for an automobile heat engine, the circuit (1) extending between a first end (3) opening into the cavity (2) and a second end (4) communicating with the atmosphere, the circuit (1) comprising at least three portions (5, 6, 7) communicating with each other, each portion circuit board extending along an axis, characterized in that the axes of the three circuit portions (5, 6, 7) are distinct.

Description

® FRENCH REPUBLIC

NATIONAL INSTITUTE OF INDUSTRIAL PROPERTY © Publication number: 3,057,335 (to be used only for reproduction orders) (© National registration number: 16 59679

COURBEVOIE © IntCI ⁸ : F16 L 55/07 (2017.01), F 02 D 9/10

A1 PATENT APPLICATION

©) Date of filing: 07.10.16. © Applicant (s): VALEO CONTROL SYSTEMS (© Priority: ENGINE Simplified joint-stock company - FR. @ Inventor (s): DAVOULT GUILLAUME and COLOMB PIERRE. (43) Date of public availability of the request: 13.04.18 Bulletin 18/15. ©) List of documents cited in the report preliminary research: Refer to end of present booklet (© References to other national documents ® Holder (s): VALEO CONTROL SYSTEMS related: ENGINE Simplified joint-stock company. ©) Extension request (s): © Agent (s): VALEO CONTROL SYSTEMS ENGINE Simplified joint-stock company.

(U4) VENT CIRCUIT OF A CLOSED CAVITY OF AN ACTUATOR.

FR 3 057 335 - A1 (6 /) The present invention describes a venting circuit (1) of a closed cavity (2) of a metering actuator (50) for fluid flow, in particular for an internal combustion engine automotive, the circuit (1) extending between a first end (3) opening into the cavity (2) and a second end (4) communicating with the atmosphere, the circuit (1) comprising at least three portions (5, 6,7) communicating with each other, each circuit portion extending along an axis, characterized in that the axes of the three circuit portions (5,6,7) are distinct.

Ventilation circuit of a closed cavity of an actuator

The present invention relates to a circuit for venting a closed cavity of an actuator, in particular an actuator for adjusting a flow rate of fluid fitted to an automobile heat engine.

The actuators making it possible to control a flow of fluid, for example the flow of combustion air from an automobile heat engine, generally have a cover closing the volume in which is housed the control mechanism of the mobile part of the actuator. This cover must be liquid tight to protect the actuator control mechanism from the entry of foreign bodies and moisture. However, the cavity closed by the cover must be placed in communication with the atmosphere, to avoid variations in pressure inside the cavity. Indeed, if the pressure inside the cavity is different from atmospheric pressure, the cover tends to deform. In applications where the cover receives a position sensor from the control mechanism, such a deformation modifies the position of the sensor, which degrades the accuracy of the measurement.

In addition, if the cavity is under vacuum, the outside air tends to return if the seal of the hood seal is insufficient. In this case, humid air can enter the cavity, which can then create condensation which accumulates and risks damaging the actuator.

Various solutions exist to ensure the venting of the cavity closed by the cover. A conventional solution is to integrate a so-called breathable patch into the hood, comprising a membrane permeable to gases but impermeable to drops of water.

Another possible solution is to put the cavity and the external atmosphere in communication, by a channel formed in the body of the actuator. The end of this channel is of small section and opens to the atmosphere.

The use of a breathable tablet increases the cost of the actuator. Indeed, in addition to the cost of the patch itself, provision must be made for the means of fixing the patch and the mounting operation. In addition, the tablet increases the size of the actuator.

When the venting is provided by a channel formed in the body of the actuator and communicating with the outside, a difficulty is to prevent droplets of liquid from entering the channel from the outside, and then being able to travel towards inside the cavity. This water intrusion can occur for example because of water splashes generated in the event of rain by the vehicle wheels. The risk of water intrusion also comes from the engine cleaning phases with a high-pressure cleaner. Conventionally, the risk of direct water intrusion is limited by positioning the outlet port of the venting channel in a place protected from wheel projections, and difficult to access with the jet of a high-pressure cleaner . Depending on the positioning of the actuator on the engine, and the positioning of the engine in the vehicle, such positioning may be impossible to find. In this case, there is a risk to the reliability of the actuator components.

The present invention aims to remedy the drawbacks of the various solutions of the state of the art.

To this end, the invention provides a circuit for venting a closed cavity of a fluid flow metering actuator, in particular for an automobile heat engine, the circuit extending between a first end opening into the cavity and a second end communicating with the atmosphere, the circuit comprising at least three portions communicating with each other, each circuit portion extending along an axis, characterized in that the axes of the three circuit portions are distinct. The venting of the closed cavity, that is to say its communication with the atmosphere, is achieved by a circuit comprising changes of direction. The venting circuit can thus bypass the functional areas of the actuator.

Advantageously, the venting circuit comprises at least two consecutive circuit portions for which the angle between the respective axes of the consecutive circuit portions is greater than 70 °.

The sudden change in direction of the venting circuit is opposed to the progression of a drop of liquid which would be returned by the end of the circuit in communication with the atmosphere.

More advantageously, the venting circuit has at least two angles greater than 70 °, the angles being formed by the respective axes of two consecutive circuit portions.

When the venting circuit includes at least two sudden changes of direction, the progression of a possible drop of liquid is made even more difficult. The risks that a drop of liquid can reach the cavity are thus very reduced.

Preferably, the axis of the circuit portion comprising the second end is inclined by less than 20 ° relative to a vertical axis, and is oriented downwards.

The portion of the circuit communicating with the atmosphere is arranged in a direction close to the vertical. It is also oriented downwards, so that gravity naturally tends to cause any drops of liquid present in this portion of the circuit to flow outwards.

Advantageously, the passage surface of the end communicating with the atmosphere is less than 2 mm ² .

Such a value ensures the equilibrium of the pressure prevailing in the cavity with the atmospheric pressure at which the ambient medium is located, while making the entry of liquid droplets very difficult.

According to one embodiment, the circuit comprises at least a portion of circuit produced by a hole produced in a body of the actuator.

A wide variety of diameter and orientation of the circuit portion can thus be obtained.

According to one embodiment, the circuit comprises at least three holes made in a body of the actuator, the holes being in fluid communication with each other.

The various holes thus make it possible to produce a circuit comprising several changes of direction.

Advantageously, the second end of the circuit is located in a fixing flange of the actuator.

Thus, the end of the venting circuit opening to the atmosphere is protected by the member on which the actuator is fixed by means of its fixing flange.

Preferably, the fixing flange has a flat surface arranged to allow sealed contact between the actuator and a retaining member of the actuator, the second end of the circuit opening into the flat surface of the fixing flange.

More specifically, the circuit portion comprising the second end of the circuit extends between a passage hole in the fixing flange and a peripheral edge of the fixing flange.

This location provides good protection for the end of the venting circuit, making it difficult for liquid droplets to enter even in the event of splashes.

According to one embodiment, the circuit portion comprising the second end of the circuit is obtained by machining the fixing flange.

This portion can thus be carried out simply, and can also be modified simply if necessary.

According to one embodiment, the portion of the circuit comprising the second end of the circuit has a groove formed on a portion of the flat surface of the fixing flange.

The flat surface of the fixing flange is easily accessible, the groove can therefore be produced easily and economically.

According to one embodiment, the portion of the circuit comprising the second end of the circuit is obtained by molding the fixing flange.

The hollow shape of the circuit portion is produced directly in the mold of the fixing flange, there is then no machining necessary, which reduces the machining costs of the part.

Preferably, the venting circuit comprises at least two consecutive circuit portions for which the ratio between the passage surface of the consecutive circuit portions is between 4 and 8.

The sudden change of section when passing from one portion of the circuit to the neighboring portion makes it more difficult to progress a droplet of liquid.

According to a preferred embodiment, at least a portion of the circuit communicates with a housing receiving an axis of rotation of a toothed wheel of a control mechanism of the actuator.

The housing was already provided for the maintenance of the axis, and is also used to form part of the venting circuit. The number of specific operations necessary to obtain the venting circuit is thus minimized.

Preferably, a portion of the circuit communicating with the housing receiving the axis of rotation communicates radially with the housing.

A portion of the venting circuit is produced in the form of a channel parallel to the housing of the axis, the channel and the housing partially overlapping. The axis is not positioned in abutment at the bottom of the housing, which means that a radial communication between the channel and the housing of the axis is obtained, even when the axis is in place.

More preferably, a portion of the circuit communicating with the housing receiving the axis of rotation communicates axially with the housing.

A portion of the venting circuit is formed by a channel joining the housing of the axis. This channel can for example be made by drilling a smaller diameter than that of the housing of the axis, for example with a stepped tool. It is thus possible to form the housing of the axis and a portion of the venting circuit during the same machining operation.

According to a preferred embodiment, at least a portion of the circuit communicates with a pre-existing through hole.

The realization of this portion of the venting circuit thus requires no specific operation. No additional cost is caused by this part of the circuit.

Preferably, the pre-existing through hole is a through hole for an actuator fixing screw.

Several screw through holes are generally available, which gives several options for choosing the geometry of the venting circuit.

According to one embodiment, a portion of the circuit communicates with a housing receiving a retaining screw in the body of an electric motor for controlling the actuator.

As before, the reuse of existing housing makes it possible to minimize the number of specific operations for obtaining the venting circuit, which limits the associated additional cost.

The invention also relates to an actuator comprising a body comprising a venting circuit as described above.

According to one embodiment, the actuator body is metallic.

The actuator can thus operate at high temperature.

Preferably, the actuator body is made of aluminum.

The actuator body can thus be easily obtained by a foundry process.

According to one embodiment, the actuator body is made of plastic.

The actuator body is thus lighter.

According to one embodiment, the material of the actuator body is a thermoplastic material.

Alternatively, the material of the actuator body is a thermosetting material.

According to one embodiment, the cavity is closed by a cover arranged to be fixed to the body of the actuator.

According to one embodiment, the cover is fixed to the body of the actuator by screws.

The cover is thus simply assembled.

According to another embodiment, the cover is fixed to the body of the actuator by clips. The tapping operation of the body to receive the cover fixing screws is thus avoided.

Advantageously, the actuator comprises a seal ensuring the seal between the cover and the body of the actuator.

Preferably, the cover is obtained by molding a polymer.

Advantageously, the cover includes a position sensor of a movable element arranged to adjust the flow of fluid passing through the actuator.

Preferably, the cover includes an electrical connector arranged to electrically connect a motor for controlling the movable element of the actuator and a source of electrical power.

According to an exemplary embodiment, the actuator comprises a movable flap in rotation arranged to control a flow of combustion air supplying a heat engine.

The actuator is fixed to an intake distributor of the combustion air supplying the combustion engine, the actuator supplying the intake distributor.

According to another exemplary embodiment, the actuator comprises a valve movable in translation, arranged to control a flow of recirculated exhaust gases between an exhaust circuit and an intake circuit of the heat engine.

The invention will be better understood on reading the figures.

FIG. 1 represents an actuator for controlling the air flow of a heat engine, integrated into its environment,

FIG. 2 represents the motor control actuator,

FIG. 3 represents a sectional view of the actuator of FIGS. 1 and 2,

FIG. 4 represents a venting circuit according to the invention,

FIG. 5 is a sectional view of the body of the actuator, illustrating the venting circuit,

Figure 6 shows the body of the air flow control actuator.

FIG. 1 shows an actuator 50 for controlling the flow rate of air supplying combustion air to an automobile heat engine. When used on a positive-ignition engine, the actuator 50 is called a throttle body. In FIG. 1, the actuator 50 is integrated into its environment.

As can be seen in FIG. 1, the actuator 50 is fixed to an intake distributor 40 of the combustion air supplying the heat engine, the actuator 50 supplying the intake distributor 40.

The operation of the actuator 50 is conventional: the body 10, shown in FIG. 6, supports all of the components of the actuator 50. In addition, the body 10 defines a passage conduit for the intake gases. The actuator 50 comprises a flap 22 movable in rotation arranged to control a flow of combustion air supplying a heat engine.

The rotation of the flap 22 makes it possible to vary the flow rate passing through the throttle housing 50. For this, and as shown in FIG. 3, an electric motor 24 rotates the flap 22, via the control mechanism 20. For this, a pinion 25 integral with the shaft of the electric motor 24 meshes with an intermediate toothed wheel 16, which itself drives a toothed wheel linked in rotation with the shaft 28 of the flap 22. A permanent magnet 27 is fixed to the end of the rotation shaft 28 of the shutter 22. A position sensor sensitive to the magnetic field of the magnet 27 makes it possible to determine the angular position of the shutter 22, and from there to ensure a control of the position of the shutter in order to '' ensure the air flow setpoint. Control is here provided by the electronic control unit controlling the operation of the heat engine, not shown.

The entire control mechanism 20 for the rotation of the flap 22 is disposed in a cavity 2 of the body 10 of the actuator. The cavity 2 is closed by a cover 18 arranged to be fixed to the body 10 of the actuator 50.

In the example shown in particular in FIG. 2, the cover 18 is fixed to the body 10 of the actuator 50 by screws 19.

The actuator 50 comprises a seal 26 ensuring the seal between the cover 18 and the body 10 of the actuator 50. The cover 18 thus protects the components located in the cavity 2 from the intrusion of external bodies, such as dust and water drops.

In addition to its protective role, the cover 18 also incorporates other functions.

Thus, the cover 18 includes an electrical connector 23 arranged to electrically connect a control motor 24 of the movable element of the actuator 50 and a source of electrical power.

The cover 18 comprises a position sensor 21 of a movable element 22 arranged to adjust the flow of fluid passing through the actuator 50. In other words, in the example shown, the position sensor 21 is fixed on the cover 2. The position sensor 21 is here a Hall effect sensor.

In the example considered, the body 10 of the actuator 50, shown in FIG. 6, is metallic. More specifically, the body 10 of the actuator 50 is made of aluminum.

The cover 18 is obtained by molding a polymer.

The connection between the cover 18 and the body 10 being sealed by means of the seal 26, the pressure of the air enclosed in the cavity 2 varies as a function of temperature variations. For example, if the temperature decreases, the pressure in cavity 2 will decrease. This depression, which applies over the entire surface of the cover 18, tends to deform the latter, the surface of the cover 18 then tending to approach the body 10.

Conversely, if the temperature in the cavity 2 increases, the pressure increases, which tends to deform the cover 18 in the other direction. The surface of the cover 18 moves away from the body 10, taking a domed shape. These pressure variations in the cavity 2 must be avoided. Indeed, the presence of a vacuum inside the cavity 2 would tend to suck in the outside air, possibly charged with humidity. The seal 26 may not be sufficient to guarantee sealing. The intrusion of humidity inside the cavity is a risk for the various components, which could oxidize, which presents a risk for the reliability of the components, and consequently of the actuator 50. In addition, the variations in shape of the cover 18 would vary the position of the position sensor 21, and hence the distance between the position sensor 21 and the permanent magnet 27. This variation in distance tends to vary the magnetic field surrounding the sensor position 21 and thus decrease the accuracy of the position measurement, and should therefore be avoided.

It is therefore necessary to ensure that the pressure inside the cavity 2 can equalize with atmospheric pressure. For this, a communication must exist between the cavity 2 and a point located outside of the actuator 50, therefore in communication with the atmosphere. The communication between the interior of the cavity 2 and the atmosphere is called "venting".

A through hole, forming a channel through which air can circulate, can be produced between the cavity 2 and the external atmosphere. This makes it possible to prevent the pressure inside the cavity 2 from being different from atmospheric pressure. One difficulty is to prevent drops of water from rising up the channel and thus entering the cavity 2, which again would risk, in the long term, causing the oxidation of the components located inside the cavity 2 .

Indeed, the actuator 50 can receive water splashes. These projections can come, for example, from the wheels of the vehicle when driving in heavy rain, or from a washing of the engine with a high-pressure cleaner.

The object of the invention is to provide a venting circuit preventing the rise of drops of water from the outside, thanks to the shape of the circuit. In addition, the invention aims to minimize the number of specific operations necessary for the manufacture of the venting circuit.

The invention provides a venting circuit 1 of a closed cavity 2 of a metering actuator 50 for fluid flow, in particular for an automobile heat engine, the circuit 1 extending between a first end 3 opening into the cavity 2 and a second end 4 communicating with the atmosphere, the circuit 1 comprising at least three portions 5,6,7 communicating with each other, each portion of the circuit extending along an axis, characterized in that the axes of the three portions 5,6,7 are separate.

The venting of the closed cavity 2, that is to say its putting into communication with the atmosphere, is carried out by a venting circuit 1 comprising changes of direction.

In Figure 4, there is shown the periphery of the venting circuit 1 without representing the body. The venting circuit 1 comprises at least two consecutive circuit portions for which the angle between the respective axes of the consecutive circuit portions is greater than 70 °. In particular, the angle between the portion 7 of the circuit 1 and the portion 8 is substantially equal to 90 °.

The venting circuit 1 comprises the portions 5, 6, 7, 8 and 9. The end 3 represents the end of the circuit located in the cavity, and the end 4 the end of the circuit located in the atmosphere. The arrows F1 and F2 show diagrammatically the air circulation between the cavity and the outside. This case corresponds to an increase in temperature in cavity 2.

More specifically, the venting circuit 1 comprises at least two angles greater than 70 °, the angles being formed by the respective axes of two consecutive circuit portions.

The second angle greater than 70 ° is for example the angle between the portion 8 and the portion 9, which here is also substantially equal to 90 °. The angle between the portions of the circuit is understood to mean the angle formed by their respective axes, when those are concurrent. When the axes of the circuit portions are not concurrent, the angle is the apparent angle when the axes are observed in the direction of the line perpendicular simultaneously to the two axes.

By creating a venting circuit with multiple changes of direction, the progression of water droplets is made very difficult.

The axis of the circuit portion comprising the second end 4 is inclined by less than 20 ° relative to a vertical axis, and is oriented downwards. In the example in FIG. 4, the circuit portion is vertical, and points downwards. The term "down" means oriented in the direction of movement created by the phenomenon of gravity. In other words, the weight of a drop of water in the portion of circuit 9 tends to reject this drop to the outside, after joining the end 4 of the circuit.

The venting circuit 1 comprises at least two consecutive circuit portions for which the ratio between the passage surface of the consecutive circuit portions is between 4 and 8. This is the case for example of the portions 6 and 7 of the circuit 1 This is also the case for sections 8 and

7. Sudden changes in passage area, like sudden changes in direction, make it more difficult to progress possible water droplets and improve the reliability of the venting circuit. By passage surface is meant the surface transverse to the axis of a portion of the circuit.

The passage surface of the end 4 communicating with the atmosphere is less than 2 mm ² .

A value between 1 mm ² and 2 mm ^{2 is} sufficient to ensure pressure balance, and makes water intrusion difficult. This value is sufficient to prevent the end of the venting circuit from becoming blocked, for example due to accumulation of deposits.

The circuit 1 comprises at least a portion of the circuit produced by a hole produced in a body of the actuator 50.

In the example considered, the circuit comprises at least three holes made in the body 10 of the actuator 50, the holes being in fluid communication with each other.

The circuit 1 is here produced by a succession of holes 5,6,7,8,9 connected together so as to form a venting circuit passing through the body 10 of the actuator.

As can be seen in FIGS. 2 and 3, the second end 4 of the circuit is located in a fixing flange 11 of the actuator 50.

Thus, the end 4 of the venting circuit 1, opening to the atmosphere, is protected from splashing water by the intake distribution of the engine.

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The fixing flange 11 has a flat surface 12 arranged to allow sealed contact between the actuator 50 and an actuator holding member 50, the second end 4 of the circuit opening into the flat surface 12 of the flange. attachment 11. The intake distributor 40 of the engine is here the actuator holding member.

As shown in FIG. 2, the portion of the circuit 9 comprising the second end 4 of the circuit extends between a passage hole 17 of the fixing flange 11 and a peripheral edge of the fixing flange 11.

This location ensures good protection against water intrusion at the end 4 of the venting circuit 1.

The circuit portion 9 comprising the second end 4 of the circuit is obtained by machining the fixing flange 11.

This portion can thus be carried out simply. In addition, if the orientation of the actuator 50 must change, for example during the development of a new motor application, the orientation of the portion 9 comprising the end 4 opening into the atmosphere can be easily modified, to respect the orientation close to the vertical mentioned above.

The portion of circuit 9 comprising the second end of circuit 4 has a groove formed on a portion of the flat surface 12 of the fixing flange 11.

As can be seen in Figures 4, 5, and 6, at least a portion of the circuit 1 communicates with a housing 14 receiving an axis of rotation 15 of a toothed wheel 16 of a control mechanism 20 of the actuator 50.

The housing 14 was already necessary for the maintenance of the axis 15 of the intermediate wheel 16, and is also used to form part of the venting circuit 1.

The circuit portion 5 communicating with the housing 14 receiving the axis of rotation 15 communicates radially with the housing 14.

As illustrated in FIG. 4, a portion of the venting circuit 1 is produced in the form of a channel 5 parallel to the housing 14 of the axis 15, the channel 5 and the housing 14 partially overlapping. The axis 15 is mounted tightly in the housing 14. The axis 15 is not positioned in abutment at the bottom of the housing 14, the free space at the bottom of the housing 14 forms the circuit portion 6. A radial communication between the channel 3 and the housing of the axis 14 is obtained, via the portion 6, even when the axis 15 is in place.

The circuit portion 7 communicating with the housing 14 receiving the axis of rotation 15 communicates axially with the housing 14.

The circuit portion 7 is machined in the body 10 at the same time as the housing 14 of the axis 15, using a stepped tool. A part of the tool carries out the bore of the housing 14 and another part of the tool, at the end, carries out the bore of the portion 7, of the same axis and smaller diameter than the housing 14. The time cycle of the machining operation of the housing 14 of the axis 15 is not changed, only a specific tool is necessary.

At least a portion of the circuit 1 communicates with a pre-existing through hole 8.

Indeed, the circuit portion 7 communicates with the pre-existing through hole 8 which is here a passage hole 17 of a fixing screw 19 of the actuator 50. The passage holes 17 each allow the passage of a screw fixing the actuator 50 to the intake distributor 40 of the engine. The production of this portion of the circuit therefore requires no specific machining.

The invention described here relates to a venting circuit 1 of a closed cavity 2 of an actuator 50. The invention also relates to an actuator 50 comprising a body 10 comprising a venting circuit 1 as described above.

According to embodiments not shown, the venting circuit of the actuator 50 and the associated actuator can also include one or more of the characteristics below, considered individually or combined with each other:

The circuit portion comprising the second end 4 of the circuit can be obtained by molding the fixing flange 11.

The hollow shape of the circuit portion is produced directly in the mold of the fixing flange, there is then no machining necessary, which reduces the machining costs of the part.

A portion of the circuit can communicate with a housing receiving a retaining screw in the body 10 of an electric motor 24 for controlling the actuator 50.

As before, the reuse of existing housing makes it possible to minimize the number of specific operations for obtaining the venting circuit, which limits the associated additional cost.

The body 10 of the actuator 50 may be made of plastic.

The actuator body is thus lighter.

According to one embodiment, the material of the body 10 of the actuator 50 is a thermoplastic material. Alternatively, the material of the body 10 of the actuator 50 may be a thermosetting material.

The cover 18 can be fixed to the body 10 of the actuator 50 by clips. The tapping operation of the body to receive the cover fixing screws is thus avoided.

The actuator 50 may include a valve movable in translation, arranged to control a flow of recirculated exhaust gases between an exhaust circuit and an intake circuit of the heat engine.

Of course, the invention is in no way limited to the embodiments described and illustrated, which have been given only by way of examples.

Claims (12)

1. Venting circuit (1) of a closed cavity (2) of a metering actuator (50) of fluid flow, in particular for an automobile heat engine, the circuit (1) extending between a first end (3) opening into the cavity (2) and a second end (4) communicating with the atmosphere, the circuit (1) comprising at least three portions (5,6,7) communicating with each other, each portion of circuit s extending along an axis, characterized in that the axes of the three circuit portions (5,6,7) are distinct. 2. Ventilation circuit (1) according to claim 1, comprising at least two consecutive circuit portions for which the angle between the respective axes of the consecutive circuit portions is greater than 70 °. 3. Ventilation circuit (1) according to claim 2, comprising at least two angles greater than 70 °, the angles being formed by the respective axes of two consecutive circuit portions. 4. Venting circuit (1) according to one of the preceding claims, the passage surface of the end (4) communicating with the atmosphere being less than 2 mm ² . 5. Ventilation circuit (1) according to one of the preceding claims, the circuit comprising at least three holes made in a body (10) of the actuator (50), the holes being in fluid communication with each other. 6. Ventilation circuit (1) according to one of the preceding claims, the second end (4) of the circuit being located in a fixing flange (11) of the actuator (50). 7. Venting circuit (1) according to the preceding claim, the fixing flange (11) comprising a flat surface (12) arranged to allow sealed contact between the actuator (50) and a member for holding the actuator (50), the second end (4) of the circuit opening into the flat surface (12) of the fixing flange (11). 8. Venting circuit (1) according to claim 6 or 7, the circuit portion comprising the second end (4) of the circuit being obtained by machining the fixing flange (11). 9. Ventilation circuit (1) according to one of the preceding claims, at least a portion of the circuit communicating with a housing (14) receiving an axis of rotation (15) of a toothed wheel (16) of a mechanism control (20) of the actuator (50). 10. Ventilation circuit (1) according to one of the preceding claims, at least a portion of the circuit communicating with a pre-existing through hole, the pre-existing through hole being a through hole (17) of a fixing screw of the 'actuator (50). 11. Actuator (50) comprising a body (10) comprising a venting circuit (1) according to one of 5 previous claims. 12. Actuator (50) according to the preceding claim, comprising a flap (22) movable in rotation arranged to control a flow of combustion air supplying a heat engine.