EP4045350A1 - Shutter device for a front-end air intake of a motor vehicle comprising a shutter disconnection device - Google Patents

Abstract

The invention relates to a shutter device (1) for a front-end air intake of a motor vehicle, comprising: - a support frame (3), - at least two shutters (5) comprising a shutter body (5a) and a first end (5b) connected to the support frame (3). According to the invention, the first end (5b) of a first shutter (5) comprises a device for disconnecting (60) the first shutter (5), and the first end (5b) of a second shutter comprises a device for disconnecting (60) the second shutter (5), each disconnection device (60) comprising: - a first portion (61) connected to the shutter body (5a), and - a second portion (62) arranged opposite the first portion (61), each shutter device (1) comprising at least one stop (9), the first portion (61) and/or the shutter body (5a) being configured to come into contact with the stop (9).

Description

DESCRIPTION

TITLE OF THE INVENTION: BLOCKING DEVICE FOR FRONT FRONT AIR INLET OF MOTOR VEHICLES INCLUDING A SHUTTER DESOLIDARIZATION DEVICE

[1] The present invention relates to the field of motor vehicle front face air flow shut-off devices, and more specifically a shut-off device comprising a shutter disconnection device.

[2] The front faces of motor vehicles generally have one or more main air inlets through which an air flow enters the direction of the front compartment of the motor vehicle. Behind these air inlets are generally placed motor vehicle heat exchangers, such as that used for air conditioning of the passenger compartment and / or that used for cooling the engine.

[3] It is also known to have, in the air path passing through the main air inlets, a support frame comprising one or more flaps mounted to pivot and capable of taking a multiplicity of different angular positions, between a position opening and a closed position and thus forming a shutter device similar to a louver. This shutter is sometimes referred to as an active grille shutter, or a controlled air intake module. Such a shutter device can also be referred to by the acronym AGS (for "Active Grille Shutter").

[4] The shutter device adjusts the air flow through the air inlets and arriving at the heat exchangers. It is thus possible to optimize the efficiency of these heat exchangers as a function of requirements by varying the quantity of air which they receive. In addition, at high speed, the shutters in the closed position make it possible to reduce the drag coefficient of the motor vehicle and thus improve the aerodynamics of said motor vehicle. The shutter device therefore makes it possible to reduce energy consumption and pollution when the engine does not need to be cooled by the outside air. [5] However, it can happen that following shocks a shutter breaks and can no longer fulfill its role of regulating the incoming air flow. This broken shutter generally remains attached to the support frame and is difficult to detect without direct visual inspection. The broken shutter is usually removed manually and possibly replaced only during this visual inspection. However, the time between breakage and the moment when the broken shutter is withdrawn can be long and have a negative impact on the performance of the shutter device, in particular if the broken shutter remains in the closed position.

[6] The object of the present invention is therefore to at least partially overcome the drawbacks of the prior art and to provide a closure device in which a plurality of broken flaps do not remain in place in the support frame.

[7] The present invention therefore relates to a closure device for the front face of a motor vehicle air inlet comprising: a. a support frame having two side uprights and two end cross members connecting the two side uprights, b. - at least two flaps arranged within the support frame and pivoting about a pivot axis between a first open end position and a second closed end position, each flap comprising a shutter body, a first end connected to the support frame by a first pivot link. vs. According to the invention, the first end of a first shutter comprises a device for separating said first shutter, and d. the first end of a second flap also comprises a device for separating said second flap, e. each decoupling device comprising: i. - a first part connected to the shutter body, and ii. - a second part arranged opposite the first part and comprising the first pivot connection with the support frame, f. each closure device comprising at least one stop, the first part of the disconnecting device and / or the shutter body being configured to come into contact with said at least one stop, so that when the first part of the disconnecting device and / or the shutter body are in contact with said stopper, the first and the second part move away from each other by the rotation of the second part.

[8] The term “separation” is understood to mean the detachment of the shutter from the support frame, or the separation of the two parts of the separation device or even the separation of the shutter, in particular the body of the shutter and the support frame.

[9] According to one aspect of the invention, the first and the second part of the uncoupling device are connected by a male / female device comprising at least a first contact zone so as to transmit the rotational movements of a device. 'drive the shutter body to the first open end position and at least one second contact zone so as to transmit the rotational movements of the drive device to the shutter body to the second closed end position, at least one of the first or second contact areas of the male / female device forming an angle with a parallel to the pivot axis.

[10] According to another aspect of the invention, only the first contact zone between the first and the second part of the uncoupling device forms an angle with a parallel to the pivot axis.

[11] According to another aspect of the invention, the first contact area of the male / female device and the second contact area of the male / female device both form an angle with a parallel to the pivot axis.

[12] According to another aspect of the invention, the male / female device comprises: a. - a first base arranged on the first part of the uncoupling device b. - a second base arranged on the second part of the uncoupling device, opposite the first base, c. - at least one male member disposed on one or other of the first or second bases, said male member projecting parallel to the pivot axis, and d. - At least one female member complementary to the at least one male member and disposed on the base facing the base carrying the at least one male member.

[13] According to another aspect of the invention, the at least one male member or female member are made on a first ring concentric with the pivot axis and projecting parallel to said pivot axis and that the at least one male member or Complementary female member are produced on a second ring which is also concentric with the pivot axis and protrudes parallel to said pivot axis, a. the first crown being intended to fit inside the second crown, b. the outer wall of the first ring and the inner wall of the second ring comprising a bead / groove pair perpendicular to the pivot axis and coming to fit into one another so as to clip the first part with the second part.

[14] According to another aspect of the invention, the first part of the uncoupling device and the body of the shutter are made in one piece.

[15] According to another aspect of the invention, the shutter body is extruded and the first part of the disconnecting device is an insert attached to one end of said shutter body.

[16] According to another aspect of the invention, that the first part of the uncoupling device comprises a pin projecting perpendicularly to the pivot axis and intended to come into contact with a stop.

[17] According to another aspect of the invention, the drive device is configured to extend the rotational movement of the shutter when the latter comes into contact with the at least one stopper and to detect the resistance to the rotation of the shutter. at least one flap and to stop its rotation at a given resistance value, said drive device also being configured to stop its rotation when it reaches a predetermined stroke exceeding that necessary to achieve the stopper without encountering resistance to the rotation of the at least one shutter and sending an error signal to an electronic management system.

[18] According to another aspect according to the invention, a stop is arranged on each end cross member so that each corresponding stop comes into opposition with the pivoting of the first flap when it is in an extreme position and of the second flap when the latter is in the opposite extreme position.

[19] Obviously, the invention also relates to a shutter for a closure device as described above.

[20] The shutter according to the invention comprises a shutter body, a first end adapted to be connected to a support frame by a first pivot connection, said first end is optionally connected to a drive device, moreover the shutter comprises in particular a second end, opposite the first end, capable of being connected to the support frame by a second pivot connection, a. characterized in that the first end of the at least one flap comprises a device for disconnecting said flap, b. said uncoupling device comprising: i. - a first part connected to the shutter body, and ii. - a second part arranged opposite the first part and comprising in particular the first pivot connection with the support frame and possibly the connection with the drive device,

[21] the first part of the disconnecting device and / or the shutter body being configured so that when the first part of the disconnecting device and / or the shutter body come into contact with a stop, the first and the second part move away from each other by the rotation of the second part.

[22] By disconnection, we mean disconnection, or disconnection of the two parts of the disconnection device. [23] Other characteristics and advantages of the present invention will emerge more clearly on reading the following description, provided by way of illustration and not limiting, and the appended drawings in which: a. the [Fig. 1] shows a schematic perspective representation of the rear face of a closure device when the flaps are in the closed end position, b. the [Fig. 2] shows a schematic perspective representation of the rear face of a closure device when the shutters are in the extreme open position, c. the [Fig. 3] shows a schematic perspective representation of the interior of the drive device in the closed end position, d. the [Fig. 4] shows a schematic perspective representation of the interior of the drive device in the open end position, e. the [Fig. 5] shows a schematic perspective representation of a shutter 5, f. the [Fig. 6] shows a schematic exploded perspective view of a shutter 5, g. the [Fig. 7] shows a schematic perspective representation of the first pivot link, h. the [Fig. 8] shows a schematic perspective representation of the exterior of the training device, i. the [Fig. 9] shows a schematic perspective view of the second pivot link, j. the [Fig. 10] shows a schematic perspective view of the uncoupling device, k. the [Fig. 11] shows a schematic representation in exploded perspective of the uncoupling device,

L. the [Fig. 12] shows a schematic perspective representation of the spacing of the first and second parts of the uncoupling device, mr. the [Fig. 13] shows a schematic perspective representation of the first part of the uncoupling device, n. the [Fig. 14] shows a schematic perspective representation of the second part of the uncoupling device, o. the [Fig. 15] shows a schematic perspective and sectional representation of the uncoupling device, p. the [Fig. 16] schematically illustrates the closure device according to the invention.

[24] In these figures, identical elements bear the same reference numerals.

[25] The following embodiments are examples. Although the description refers to one or more embodiments, this does not necessarily mean that each reference relates to the same embodiment, or that the characteristics apply only to one embodiment. Simple features of different embodiments can also be combined or interchanged to provide other embodiments.

[26] In the present description, it is possible to index certain elements or parameters, such as for example first element or second element as well as first parameter and second parameter or even first criterion and second criterion, and so on. In this case, it is a simple indexing to differentiate and name similar elements or parameters or criteria, but not identical. This indexing does not imply a priority of one element, parameter or criterion over another and such names can easily be interchanged without departing from the scope of the present description. This indexation does not imply an order in time, for example, to assess this or that criterion.

[27] In the following description, the term “upper” and “lower” is understood to mean the arrangement of the elements on the front face air intake shutter device in the mounted state of the shutter device on the motor vehicle.

[28] The [Fig. 1] and [Fig. 2] show a closure device 1 for the front face of a motor vehicle air inlet, respectively of its front face and of its face. back. By front face is meant here the face of the closure device 1 intended to be oriented towards the front of the motor vehicle. By rear face is meant here the face of the closure device 1 opposite to the front face and intended to be oriented towards the rear of the motor vehicle.

[29] The closure device 1 comprises a support frame 3 having two lateral uprights 3a and two end crossbars 3b, 3b 'connecting the two lateral uprights 3a to each other, thus defining an opening of the support frame 3. More particularly, the support frame 3 has an upper cross member 3b and a lower cross member 3b ', these orientations arbitrarily corresponding to the arrangement of the closure device 1 in the mounted state in the motor vehicle. In the example presented in [Fig. 1] and [Fig. 2], the opening of the support frame 3 is divided in two by a central upright 3c connecting the upper cross member 3b and the lower cross member 3b '.

[30] The support frame 3 has at least one flap 5 arranged inside the opening. This at least one shutter 5 is mounted to pivot about a pivot axis P (visible in [Fig. 3] and [Fig. 4]) between a first open end position (visible in [Fig. 2] and [ Fig. 4]) and a second closed end position (visible in [Fig. 1] and [Fig. 3]). When at least one flap 5 occupies its first open end position, the air flow can pass through the opening of the support frame 3. When at least one flap 5 occupies its second closed end position, said at at least one flap 5 obstructs the opening of the support frame 3 and opposes the passage of the air flow. Obviously, the flaps 5 are able to adopt any intermediate position.

[31] Still in the example illustrated in [Fig. 1] and [Fig. 2], the support frame 3 comprises a plurality of flaps 5 forming at least one set of flaps 5 arranged parallel to each other on the same plane and are adjacent. In the present case, the support frame 3 comprises two sets of flaps 5 each disposed in an opening. These openings are separated by the central upright 3c. The shutters 5 are in particular arranged horizontally and one above the other.

[32] In other words, when the flaps 5 are in the end open position as shown in [Fig. 4], namely that they extend in a direction longitudinal and transverse with respect to the support frame 3, the opening or the air inlet is unobstructed and the air flow can pass through the passage, or the opening, defined by the support frame 3. When the all of the flaps 5 are in the closed end position, that is to say they extend in a transverse and vertical direction relative to the support frame 3, or for example relative to the axes of a vehicle when the device shutter is installed in a vehicle, the air passage, or the opening, defined by the support frame 3, namely an air inlet, is blocked and the air cannot pass through the support frame 3. As illustrated in [Fig. 1], in this closed position, all of the flaps 5 constitute an obstacle which opposes, by their front surface, the circulation of the air flow, the opening of the support frame 3 is thus fully closed. In other words, the closure device 1 is configured to go from a closed configuration where the flaps 5 completely block the opening of the support frame 3, and therefore the passage of the air flow F, to an open configuration where the flaps 5 are positioned so as to allow the air flow F to pass with a maximum flow rate.

[33] In addition, the support frame 3 has at least one drive device 7 (visible in [Fig. 2]) configured to control the positioning, and therefore the pivoting, of the flaps 5 between their first open end position and their second closed end position.

[34] The drive device 7 comprises in particular an actuator 7a and a control member 7b, visible in [Fig. 3] and [Fig. 4] In [Fig. 2], the actuator 7a and the control unit 7b are covered by a protective cover 7c. In the example illustrated in [Fig. 3] and [Fig. 4], the actuator 7a is connected to a flap 5, called the motor flap 51a of the set of flaps 5, in order to pivot this motor flap 5a. The other flaps 51b of the set of flaps 5 are connected to the motor flap 51a by the control member 7b, for example a connecting rod, which transmits the pivoting movement of the motor flap 5a to the other flaps 51b.

Other modes of transmission of the rotational movements of the actuator 7a to the set of shutters 5 can quite be imagined. For example, the actuator 7a can be connected directly to the control member 7b by a lever, the actuator 7a then translating said control member 7b in order to simultaneously rotate the shutters. Likewise, the actuator can be connected to the motor shutter 51a at one end 5b, and the control member 7b is connected to the opposite end 5c of the motor shutter 51a as well as to the other shutters 51b.

[35] Still in the example illustrated in [Fig. 1], [Fig. 2], [Fig. 3] and [Fig. 4], the drive device 7 is arranged on the central post 3c of the support frame 3 in order to be able to pivot two sets of flaps 5 simultaneously. According to a variant not shown here, the drive device 7 can be arranged on a lateral upright 3a of the support frame 3 so as to pivot a single set of flaps 5. In addition, the drive device 7 is arranged here. on the rear side of the shutter 1.

[36] As shown in [Fig. 5], at least one flap 5 comprises in particular an elongated flap body 5a, a first end 5b and a second end 5c, opposite to the first end 5b. The shutter 5, generally made of plastic material, may for example be an extruded shutter 5 as illustrated in [FIG. 6]. In this case, the shutter body 5a is extruded and the first 5b and second 5c ends are inserts attached to the ends of said shutter body 5a. However, it is quite possible to imagine another type of shutter 5, for example a shutter 5 made in one piece, in particular by molding.

[37] The first end 5b of the shutter 5 is connected to the support frame 3, by a first pivot link (visible in [Fig. 7]), and connected to the drive device 7. In [Fig. 7], the control unit 7b as well as a shutter 5 have been removed for ease of understanding. The first end 5b can be directly connected to the actuator 7a in the case of a motor shutter 5a. The first end 5b can also be connected to the control member 7b by means of a link arm 55 extending in a general direction perpendicular to the pivot axis P.

[38] The first pivot connection can for example be produced by the coupling of a first notch 71 made in a wall 32 of the drive device 7 perpendicular to the pivot axis P. The first end 5b of the shutter 5 comprises quant to it a second circular notch 53 (visible in [Fig. 6]) and complementary to the first notch 71. The first end 5b of the flap 5 is inserted into the first notch 71 so that the wall 32 comes into the second notch 53.

[39] As shown in [Fig. 8], the first end 5b of the shutter 5 is held in the first notch 71 by the protective cover 7c which covers the first notch 71 and closes it so as to form an orifice in which the first end 5b of the shutter 5 can pivot. .

[40] Still as illustrated by [Fig. 8], the closure device 1 comprises at least one stop 9. This stop 9 is intended in particular to come into contact with the shutter 5 when it occupies its first open end position or its second closed end position. This stopper 9 comes into opposition with the pivoting of the shutter 5 when it arrives at one of its end positions. The stop 9 can in particular be placed on the support frame 3 on a lateral upright 3a, 3b or on a central upright 3c, in particular at the level of the drive device 7. In the example shown in [Fig. 8], a stop 9 is made on the protective cover 7c. The stop 9 can also be produced directly on the support frame 3.

[41] The second end 5c is for its part connected to the support frame 3 by a second pivot connection, as shown in [Fig. 9] The second end 5c can thus include a pin 54 projecting along the pivot axis P. This pin 54 is inserted into a hole made in a wall 33 of the support frame 3 extending perpendicularly to the axis of pivoting P. Here, this wall 33 is produced on a lateral upright 3a.

[42] As shown in more detail in [Fig. 10] and [Fig. 11], the second end 5b of at least one shutter 5 comprises a device 60 for separating said shutter 5. This separating device 60 makes it possible to separate the shutter 5 and more precisely are shutter body 5a from the support frame 3 and thus allows the fall of the latter to prevent said shutter 5 from remaining in the end closed position when it is broken and causes a drop in the performance of the heat exchangers arranged behind the closure device 1.

[43] The uncoupling device 60 can in particular be placed on one or more of the shutters 5 of a set of shutters 5. As part of a device shutter 1, as illustrated in [Fig. 1] and [Fig. 2], comprising a plurality of flaps 5 forming at least one set of flaps 5 arranged horizontally and one above the other, it may be advantageous that only the upper flap 5 of said set of flaps 5 comprises a disconnecting device 60. Indeed, according to various returns and experiments, this upper flap 5 is the one which is most likely to be subject to breakage and therefore to hamper the circulation of the air flow in the opening of the support frame 3. However, it It remains more advantageous to arrange a plurality of separating device 60 on a plurality of corresponding flap 5 in order to improve the circulation of the air flow in the event of breakage.

[44] By way of explanation, the uncoupling device 60 will be explained below for a corresponding component. The closure device according to the invention comprises at least two uncoupling device 60. Obviously, each uncoupling device 60 uses the same principle and the same structural elements as described below.

[45] The uncoupling device 60 comprises in particular:

- a first part 61 connected to the shutter body 5a, and

- a second part 62 arranged opposite the first part 61.

[46] The second part 62 of the uncoupling device 60 comprises in particular the first pivot connection with the support frame 3, more precisely the second notch 53. The second part 62 also comprises the connection with the drive device 7. More precisely, the second part 62 may include the link arm 55.

[47] The first part 61 of the disconnecting device 60 and / or the shutter body 5a are in particular configured to come into contact with the at least one stop 9 when the shutter 5 occupies its first open end position or its second end position closed. For this, the first part 61 of the disconnecting device 60 may include a pin 610 projecting perpendicularly to the pivot axis P and intended to come into contact with a stop 9.

[48] The first 61 and the second 62 part can in particular be connected by a male / female device 63. This male / female device 63 comprises in particular at least one first contact area 65a so as to transmit the rotational movements of the drive device 7 to the shutter body 5a towards the first open end position and at least one second contact area 65b so as to transmit the rotational movements from the drive device 7 to the shutter body 5a towards the second closed end position. At least one of its first 65a or second 65b contact zones forms an angle with a parallel to the pivot axis P. Thus, when the first part 61 of the uncoupling device 60 and / or the shutter body 5a are in contact of a stopper 9, the first 61 and the second 62 part of the uncoupling device 60 tend to move away from each other by the rotation of the second part 62 via a sliding at the level of said contact zone 65a , 65b.

[49] Thus, when the shutter body 5a or the first part 9 comes into contact with a stopper 9, the latter is blocked and no longer rotates. The pivoting force exerted by the drive device 7 on the second part 62 is then converted into a translational force if the contact area 65a, 65b of the male / female device 63 forms an angle with a parallel to the pivot axis. P. Under normal conditions, this translational force is compensated by an opposing force exerted by the second end 5c of the shutter 5 which is attached to the support frame 3 at the second pivot connection.

However, in the case where the shutter 5 is broken, in particular at the level of its shutter body 5a, this opposing force is not present and the translational force causes sliding of the first part 61 and of the portion of the body. flap 5c which is attached to it along the contact zone 65a, 65b of the male / female device 63 forming an angle with a parallel to the pivot axis P, as illustrated in [Fig. 1] and [Fig. 2] On the [fi and [Fig. 2], the pivoting and translational forces are represented by arrows. This translation takes place until the complete uncoupling of the first part 61 from the second part 62 and the fall by gravity of said first part 61 and of the shutter body portion 5c which is attached to it.

This is particularly useful in order to prevent a broken shutter 5 from getting stuck in the opening of the support frame in a position which could affect the performance of the motor vehicle. [50] The drive device 7 can in particular be configured to extend the rotational movement of the shutter 5 when the latter comes into contact with the at least one stop 9. When the shutter 5 comes into contact with the stop 9, the drive device 7, and more precisely its actuator 7a, can detect the resistance to rotation of shutter 5, for example by measuring the electric current at actuator 7a. If the resistance to rotation increases, the drive device can in particular stop its rotation when it reaches a given resistance value.

[51] If the resistance to rotation does not increase, for example because the shutter 5 is broken, the driving device 7 can also be configured to stop its rotation when it reaches a predetermined stroke exceeding that necessary to reach the stop 9. The drive device 7 can then send an error signal to an electronic management system in order for example to light up a warning light on the instrument panel in order to warn the user of a problem. shutter level 1.

[52] In the example presented in [Fig. 10], in [Fig. 11] and in [Fig. 12], only the first contact zone 65a between the first 61 and the second 62 part of the uncoupling device 60 forms an angle with a parallel to the pivot axis P. This first contact zone 65a is particularly stressed when the shutter 5 comes into contact with a stop 9 in its first open end position as in [FIG. 8]. However, it is quite possible that, conversely, this first contact zone 65a is particularly stressed when the shutter 5 comes into contact with a stopper 9 in its closed end position. In this example, the second contact zone 65b is for its part parallel to the pivot axis P and does not allow separation of the first 61 and second 62 parts of the uncoupling device 60.

[53] According to an embodiment not shown, the first contact zone 65a and the second contact zone 65b of the male / female device 63 can both form an angle with a parallel to the pivot axis P. Thus, according to this embodiment, the separation of the first 61 and second 62 parts of the uncoupling device 60 can be done both in the first open end position and in the second closed end position. [54] [Fig. 13] shows an isolated perspective view of the first part 61 of the uncoupling device 60. [FIG. 14] shows an isolated perspective view of the second part 61 of the uncoupling device 60. [FIG. 15] finally shows a sectional view of the uncoupling device 60. As shown in these figures [FIG. 13], [Fig. 14] and [Fig. 15] the male / female device 63 may include:

- a first base 66a disposed on the first part 61 of the uncoupling device 60,

- a second base 66b disposed on the second part 62 of the uncoupling device 60, facing the first base 66a,

- at least one male member 67a disposed on one or the other of the first 66a or second 66b bases, said male member 67a projecting parallel to the pivot axis P, and

- at least one female member 67b complementary to at least one male member 67b and disposed on the base 66a, 66b opposite the base 66a, 66b carrying the at least one male member 67b.

In the example shown in [Fig. 13], [Fig. 14] and [Fig. 15], the first base 66a and the second base 66b each comprise four male members 67a and four female members 67b; The first part 61 here also comprises an extension 612 starting from the first base 66a and extending parallel to the pivot axis P and intended to come to make the connection with an extruded shutter body 5a. In the case where the shutter 5 is made in one piece, this extension is absent and the first base 66a comes integral with the shutter body 5a.

[55] The at least one male member 67a or female member 67b can in particular be produced on a first ring 68a concentric with the pivot axis P and projecting parallel to said pivot axis P. The at least one male member 67a or member complementary female 67b can be made on a second ring 68b also concentric with the pivot axis P and projecting parallel to said pivot axis P. The first ring 68a is intended to fit inside the second crown 68b in the mounted state as shown in [Fig. 15]. The outer wall of the first ring 68a and the inner wall of the second ring 68b comprise a bead 69a / groove 69b pair perpendicular to the axis of pivoting P and which fits into one another so as to clip the first part 61 with the second part 62.

[56] In the example presented in [Fig. 13], [Fig. 14] and [Fig. 15], the first crown 68a is carried by the first part 61 and the second crown 68b by the second part 62. It is of course quite possible to imagine a scenario in which the reverse is possible. In addition, the groove 69b is here produced on the internal face of the second ring 68b and the bead 69a on the external face of the first ring 69a. It is also possible to imagine the reverse, that is to say that the groove 69b is made on the outer face of the first ring 69a and the bead 69a on the inner face of the second ring 68b.

[57] The presence of this elastic type interlocking fixing between the first 61 and the second part 62 allows, during the separation of these two elements, to exert an ejection force of the first part 61 during the separation. . The first part 61 and the broken shutter body 5a which is attached to it are then expelled more easily. This decreases the risk of the first part 61 getting stuck in the second part 62.

[58] The male / female device 63 can also include a keying device 630 which allows a good positioning of the second part 62 on the first part 61 of the uncoupling device 60. This allows an adequate positioning of the elements such as the link arm 55. relative to the shutter body 5a. This polarizer 630 can in particular be produced by a male member 67a and its complementary female member 67b which have a different shape with respect to the other male members 67a and female 67b.

[59] Thus, we can clearly see that the closure device 1, due to the fact that it comprises at least one shutter 5 with a disconnection device 60, or unhooking, not only makes it possible to automatically remove a broken shutter 5 without having need to perform visual inspection and manual intervention. In addition, the uncoupling device 60 can allow the detection and signaling of a broken shutter 5 so that the user of the motor vehicle can schedule a repair. [60] Figure 16 illustrates schematically the closure device 1 according to the invention. In fact, the closure device comprises two flaps 5, each comprising a disconnection device 60 at one end 5b. Here the actuator 7a is connected by means of a lever to a first disconnection device 60 which itself is connected to the motor flap 51a at the level of the end 5b. The second end 5c of the motor flap 51a is engaged with the control member 7b. The control member 7b is also connected to a second uncoupling device 60 which is engaged with the end 5b of a second flap 51b. Thus when the actuator 7a induces the pivoting of the motor flap 51a, the latter drives the translation of the control member 7b and at the same time the pivoting of the second flap 5. With such an embodiment it is possible to separate a plurality of flaps 5 with the mechanism described above. A corresponding stop 9 is intended to come into contact with each flap 5 when it occupies its first open end position or its second closed end position. This stop 9 comes into opposition with the pivoting of each flap 5 when it arrives at one of its end positions. The stop 9 can in particular be placed on the support frame 3 on a lateral upright 3a,

3b or on a central post 3c. The stop 9 may for example be arranged on the lower end cross member 3b ’and on the upper end cross member 3b, or in other words, on the opposite end cross members. In this case, the stop comes in opposition with the pivoting of each flap when the motor flap 51a is in an extreme position, for example in the open position and when the second flap 51b is in the opposite extreme position, therefore according to the same example, the shutter position or vice versa.

[61] According to an embodiment not shown, it is also possible to arrange a third shutter also comprising a disconnection device. The control unit connecting the three components. It is also possible to arrange a separation device on a first and last shutter and no separation device on the shutter arranged between these two shutters. Since the stop element is necessary in the disconnecting device, a stop should be arranged on the side and / or central upright parts of the frame near each corresponding disconnecting device.

Claims

[Claim 1] Sealing device (1) for a motor vehicle front face air inlet comprising: a. - a support frame (3) having two lateral uprights (3a) and two end crossbars (3b, 3b ’) connecting the two lateral uprights (3a), b. - at least two flaps (5) arranged within the support frame (3) and pivoting about a pivot axis (P) between a first open end position and a second closed end position, each flap (5) comprising a body shutter (5a), a first end (5b) connected to the support frame (3) by a first pivot connection c. characterized in that the first end (5b) of a first flap (5) comprises a device for separating (60) from said first flap (5), and d. the first end (5b) of a second flap also comprises a device for separating (60) from said second flap (5) e. each uncoupling device (60) comprising: i. - a first part (61) connected to the shutter body (5a), and ii. - a second part (62) arranged opposite the first part (61) and comprising the first pivot connection with the support frame (3), f. each closure device (1) comprising at least one stop (9), the first part (61) of the disconnecting device (60) and / or the shutter body (5a) being configured to come into contact with said at least a stopper (9), so that when the first part (61) of the disconnecting device (60) and / or the shutter body (5a) are in contact with said stopper (9), the first (61) and the second (62) part move away from each other by the rotation of the second part (62).

[Claim 2] Sealing device (1) according to claim 1, characterized in that the first (61) and the second (62) part of the disconnecting device (60) are connected by a male / female device (63) comprising at least a first contact zone (65a) so as to transmit the rotational movements of a drive device (7) to the shutter body (5a) towards the first open end position and at least one second zone of contact (65b) so as to transmit the rotational movements of the drive device (7) to the shutter body (5a) towards the second closed end position, at least one of the first (65a) or second (65b) contact zones of the male / female device (63) forming an angle with a parallel to the pivot axis (P).

[Claim 3] Sealing device (1) according to claim 2, characterized in that only the first contact zone (65a) between the first (61) and the second (62) part of the disconnecting device (60) forms an angle with a parallel to the pivot axis (P).

[Claim 4] Sealing device (1) according to claim 2, characterized in that the first contact area (65a) of the male / female device (63) and the second contact area (65b) of the male / female device (63) both form an angle with a parallel to the pivot axis (P).

[Claim 5] Sealing device (1) according to any one of the preceding claims, characterized in that the male / female device (63) comprises: a. - a first base (66a) arranged on the first part (61) of the uncoupling device (60) b. - a second base (66b) disposed on the second part (62) of the uncoupling device (60), opposite the first base (66a), c. - at least one male member (67a) disposed on one or other of the first (66a) or second (66b) bases, said male member (67a) projecting parallel to the pivot axis (P), and d. - at least one female member (67b) complementary to the at least one male member (67b) and disposed on the base (66a, 66b) facing the base (66a, 66b) carrying the at least one member male (67b).

[Claim 6] Sealing device (1) according to any one of claims 2 to 9, characterized in that the drive device (7) is configured to extend the rotational movement of the shutter (5) when the latter comes into contact with at least one stop (9) and to detect the resistance to rotation of at least one shutter (5) and to stop its rotation when it reaches a given resistance value, at. said drive device (7) also being configured to stop its rotation when it reaches a predetermined stroke exceeding that necessary to reach the stop (9) without encountering resistance to the rotation of the at least one shutter (5) and to raise a error signal to an electronic management system.

[Claim 7] Sealing device (1) according to any one of the preceding claims wherein a stop (9) is arranged on each end cross member (3b, 3b ') so that each stop (9) corresponding comes in opposition with the pivoting of the first shutter (5) when it is in an extreme position and of the second shutter (5) when the latter is in the opposite extreme position.

[Claim 8] Shutter (5) for a shutter device (1) comprising a shutter body (5a), a first end (5b) adapted to be connected to a support frame (3) by a first pivot connection, a. characterized in that the first end (5b) of the at least one flap (5) comprises a device (60) for disconnecting said flap (5), b. said uncoupling device (60) comprising: i. - a first part (61) connected to the shutter body (5a), and ii. - a second part (62) arranged opposite the first part

(61), c. the first part (61) of the uncoupling device (60) and / or the shutter body (5a) being configured so that when the first part (61) of the uncoupling device (60) and / or the shutter body (5a) ) come into contact with a stop (9), the first (61) and the second (62) part move away from each other by the rotation of the second part (62) i