The present application claims priority from French Application No. 22/05745 filed Jun. 14, 2022, the disclosure of which is hereby incorporated herein by reference.
The present invention concerns the field of automatic coffee machines, and more particularly the field of milk frothing devices intended to cooperate with automatic coffee machines.
The document WO2005/063093 discloses a milk frothing device including:
The main flow conduit is more particularly configured so that a vapor flow in the main flow conduit from the vapor inlet orifice and up to the mixing chamber generates a vacuum in the milk supply conduit and a vacuum in the air supply conduit and leads to a suction of milk and air into the main flow conduit.
The particular configuration of the milk frothing device described in document WO2005/063093, and more particularly of the mixing part and of the closure part, allows easy cleaning of the milk frothing device.
Nonetheless, according to document WO2005/063093, the seal is formed by a cover part, which is generally planar, and which is made of flexible material, and the milk supply conduit, the main flow conduit and the mixing chamber are delimited in part by said cover part. Thus, the milk proteins, contained in the milk flowing in the milk supply conduit and the main flow conduit, are likely to deform the cover part and therefore to modify in particular the flow cross section of the main flow conduit.
However, such a modification of the flow cross section of the main flow conduit is likely to modify, over time, the amount of air introduced into the main flow conduit, which can lead to obtaining a milk froth having a consistency which is not firm and creamy enough, and for example too liquid.
The present invention aims to remedy all or part of these drawbacks.
The technical problem underlying the invention consists in particular in providing a milk frothing device which can be easily dismantled and cleaned, while guaranteeing that a milk froth of a suitable consistency is obtained.
To this end, the present invention concerns a milk frothing device intended to cooperate with an automatic coffee machine, the milk frothing device including:
The air supply conduit comprises a calibrated air passage, for example annular, configured to define a maximum air flow rate in the air supply conduit which is independent of the seal.
The presence of such a calibrated air passage makes it possible to avoid the intake of too large amount of air into the mixing chamber, and therefore the obtaining of a milk froth which is too airy and/or provided with bubbles of large diameters.
In addition, the fact that the maximum air flow rate defined by the calibrated air passage is independent of the seal makes it possible to control the amount of air entering into the main flow conduit, since such an amount of air is not susceptible to be deteriorated by milk proteins flowing through the main flow conduit.
Thus, the milk frothing device according to the present invention can be easily dismantled and cleaned, while guaranteeing the obtaining of a milk froth having a suitable consistency.
The milk frothing device may further have one or more of the following features, taken alone or in combination.
According to one embodiment of the invention, the milk frothing device further includes an air flow rate adjustment device configured to adjust an air flow flowing in the air supply conduit. Such a configuration of the milk frothing device according to the present invention, and more particularly the presence of the air flow rate adjustment device, allows a user to adapt the consistency of the milk froth obtained according to his wishes. For example, the user can adjust the air flow rate introduced into the mixing chamber in order to obtain more or less firm milk froth.
According to one embodiment of the invention, the main flow conduit is entirely delimited by the mixing part and the closure part. Thus, the milk proteins, contained in the milk flowing in the main flow conduit, are not likely to deform the latter, and therefore to have an impact on the amount of air introduced into the mixing chamber.
According to one embodiment of the invention, the air flow rate adjustment device includes:
Such a configuration of the air flow rate adjustment device makes it possible to easily adjust the amount of air introduced into the main flow conduit by displacing the flow rate adjustment member into an adjustment position corresponding to the desired froth consistency.
According to one embodiment of the invention, the calibrated air passage is located downstream of the air flow rate adjustment device, and for example downstream of the air flow passage.
According to one embodiment of the invention, the air flow rate adjustment device comprises at least one air intake opening, the air flow passage being configured to fluidically connect the at least one air intake opening to the calibrated air passage.
According to one embodiment of the invention, the flow rate adjustment member is displaceable between a maximum adjustment position in which the flow cross section of the air flow passage is maximum, and a minimum adjustment position in which the flow cross section of the air flow passage is minimal, and for example zero or substantially zero.
According to one embodiment of the invention, the air flow rate adjustment device includes a support part fixed to the closure part and configured to support the flow rate adjustment member, the flow rate adjustment member being movably mounted relative to the support part.
According to one embodiment of the invention, the sealing element is fixed to the flow rate adjustment member. Such an arrangement of the sealing element allows easy mounting of the air flow rate adjustment device.
According to one embodiment of the invention, the sealing element and the support part delimit the air flow passage.
According to one embodiment of the invention, the at least one air intake opening is defined by a functional clearance between the flow rate adjustment member and the support part.
According to one embodiment of the invention, the flow rate adjustment member includes a manipulation part configured to be manipulated by a user so as to displace the flow rate adjustment member in the displacement direction.
According to one embodiment of the invention, the support part includes an insertion hole, and the air flow rate adjustment device further comprises a passage restriction member, such as a pin or a needle, housed at least partly in the insertion hole, the insertion hole and the passage restriction member delimiting the calibrated air passage. Such a configuration of the calibrated air passage allows easy cleaning of the milk frothing device according to the present invention, and in particular of the calibrated air passage, by removing the passage restriction member from the insertion hole and by then cleaning, in particular, the passage restriction member and the insertion hole. In addition, such a configuration of the calibrated air passage substantially limits the risks of obstruction of the calibrated air passage since the successive movements of the flow rate adjustment member in the displacement direction have the consequence of evacuating, outside the calibrated air passage, any particles, such as dust particles, retained in the calibrated air passage.
According to one embodiment of the invention, the insertion hole has a diameter greater than one millimeter, preferably greater than 1.5 millimeters.
According to one embodiment of the invention, the passage restriction member includes a lower end portion which is housed in the insertion hole.
According to one embodiment of the invention, the passage restriction member is elongated and extends along a direction of extension which is substantially parallel to the displacement direction.
According to one embodiment of the invention, the passage restriction member is secured in movement to the flow rate adjustment member. Thus, the passage restriction member is movably mounted in the insertion hole in the displacement direction.
According to one embodiment of the invention, the support part includes a bearing surface, for example provided on an upper end face of the support part, which is annular and against which the sealing element is able to be compressed.
According to one embodiment of the invention, the support part includes a recess which is formed in the bearing surface provided on the support part and which partly delimits the air flow passage. The recess may for example radially extend relative to a central axis of the bearing surface.
According to one embodiment of the invention, the mixing part includes an upper face in which the main flow conduit is formed and into which the mixing chamber opens.
According to one embodiment of the invention, the mixing part includes a receiving groove which is formed in the upper face of the mixing part and in which the seal is housed.
According to one embodiment of the invention, the mixing part includes a bearing wall which extends around the mixing chamber and the main flow conduit and which partially delimits the receiving groove, the bearing wall projecting from the upper face of the support part and the closure part being configured to bear against the bearing wall. The presence of such a bearing wall limits the risks of milk leakage in the direction of the seal, and therefore the risks of degradation of the latter by the milk proteins contained in the milk flowing in the main flow conduit.
According to one embodiment of the invention, the mixing part and the closure part are generally circular and extend substantially coaxially when the closure part occupies the closed position.
According to one embodiment of the invention, the mixing part includes an air intake channel configured to be closed by the closure part, the air intake channel connecting the air supply conduit to the main flow conduit and the seal extending around the air intake channel.
According to one embodiment of the invention, the air intake channel is formed in the upper face of the mixing part.
According to one embodiment of the invention, the closure part includes the air supply conduit. Such an arrangement of the air supply conduit makes it possible to substantially limit the risks of deterioration of the air supply conduit by the milk proteins contained in the milk flowing in the main flow conduit, and therefore to guarantee the intake of a controlled amount of air into the mixing chamber.
According to one embodiment of the invention, the junction area is planar. Such a configuration of the milk frothing device according to the present invention allows easy assembly of the milk frothing device.
According to one embodiment of the invention, the mixing part includes the milk supply conduit. Such an arrangement of the milk supply conduit makes it possible to substantially limit the risks of deterioration of the milk supply conduit by the milk proteins contained in the milk flowing in the milk supply conduit, and to therefore guarantee the intake of a controlled amount of milk into the mixing chamber.
According to one embodiment of the invention, the mixing part is made in one piece.
According to one embodiment of the invention, the milk supply conduit comprises a calibrated flow passage configured to define a predetermined milk flow rate in the milk supply conduit. These provisions make it possible to guarantee the intake of a predetermined amount of milk into the mixing chamber, and therefore the obtaining of milk froth having a suitable consistency.
According to one embodiment of the invention, the predetermined milk flow rate defined by the calibrated flow passage is independent of the seal. As a result, the amount of milk entering into the main flow channel is independent of the seal and is not likely to be deteriorated by milk proteins flowing into the main flow channel.
According to one embodiment of the invention, the main flow conduit includes a section restriction forming a milk and air suction system based on the Venturi effect. In other words, the main flow conduit is configured such that a flow of hot water/vapor in the main flow conduit from the hot water/vapor orifice and to the mixing chamber generates a vacuum in the milk supply conduit and a vacuum in the air supply conduit and causes a suction of milk and air in the main flow conduit. Such a configuration of the milk frothing device makes it possible to control the amount of air and the amount of milk entering into the mixing chamber, without requiring the presence of complex and expensive intake means.
According to one embodiment of the invention, the milk supply conduit opens into the main flow conduit close to the section restriction.
According to one embodiment of the invention, the air intake channel opens into the main flow conduit close to the section restriction.
According to one embodiment of the invention, the main flow conduit includes:
According to one embodiment of the invention, the main flow conduit is configured to allow a first mixing of vapor, milk and air respectively from the hot water/vapor inlet orifice, the milk supply conduit and the air intake channel, before their arrival in the mixing chamber.
According to one embodiment of the invention, the seal is continuous.
According to one embodiment of the invention, the seal has a constant cross-section. However, the seal could have a non-constant cross-section to improve the sealing between the mixing part and the closure part in the case of strong deformation of the latter.
According to one embodiment of the invention, the mixing chamber is of the cyclonic type and extends vertically, the main flow conduit opening into an upper part of the mixing chamber and the outlet orifice being located in a lower part of the mixing chamber. Such a configuration of the mixing chamber promotes the mixing of air, milk and hot water or steam introduced into the mixing chamber.
According to one embodiment of the invention, the main flow conduit opens tangentially into the mixing chamber. Such a configuration of the main flow conduit promotes the mixing of air, milk and hot water or steam introduced into the mixing chamber.
According to one embodiment of the invention, the mixing part includes a milk pouring conduit fluidly connected to the outlet orifice of the mixing chamber and configured to be located vertically above a container, such as a cup.
According to one embodiment of the invention, the milk frothing device includes a milk reservoir comprising an upper opening, the mixing part being arranged at the upper opening, and is for example housed at least partially in the milk reservoir.
According to one embodiment of the invention, the mixing part includes a mixing body configured to partially close the milk reservoir and to be removable relative to the milk reservoir.
According to one embodiment of the invention, the mixing body is provided with a tubular mounting portion configured to be mounted in the milk reservoir, and more particularly to be inserted into the milk reservoir via the upper opening of the milk reservoir.
According to one embodiment of the invention, the closure part is configured to cover the mixing part.
According to one embodiment of the invention, the milk supply conduit includes a milk suction tube extending vertically and opening into a lower part of the milk reservoir.
According to one embodiment of the invention, the calibrated flow passage is located downstream of the milk suction tube.
According to one embodiment of the invention, the mixing part and the closure part are configured to close the milk reservoir and to be removable with respect to the milk reservoir. In other words, the mixing part and the closure part form a lid configured to close the milk reservoir.
According to one embodiment of the invention, the milk frothing device includes a holding system configured to hold the closure part in the closed position. Such a configuration of the holding system makes it possible to avoid untimely displacement of the closure part towards the open position.
According to one embodiment of the invention, the holding system is configured to ensure a compression of the seal when the closure part is in the closed position. Such a configuration of the holding system makes it possible to improve the effectiveness of the seal, and therefore to limit the risks of fluid leakage at the seal.
According to one embodiment of the invention, the holding system is configured to press the closure part against the mixing part when the closure part is in the closed position, so as to compress the seal, and more particularly a sealing lip of the seal.
According to one embodiment of the invention, the holding system includes a locking part, such as a locking ring, movably mounted between a release position in which the locking part enables a displacement of the closure part towards the open position and a locking position in which the locking part prevents a displacement of the closure part towards the open position. Such a configuration of the holding system allows a user to be able to easily immobilize the closure part in the closed position.
According to one embodiment of the invention, the closure part includes a filling opening and a flap movable between an open position in which the flap at least partially releases the filling opening and enables an introduction of milk into the milk reservoir and a closed position in which the flap at least partially seals the filling opening.
According to one embodiment of the invention, the mixing part includes a passage opening configured to be located opposite the filling opening.
According to one embodiment of the invention, the holding system is configured to removably, that is to say temporarily and reversibly, fasten the mixing part and the closure part to the milk reservoir.
According to another embodiment of the invention, the milk frothing device includes a connecting device which is separate from the holding system and which is configured to removably, that is to say temporarily and reversibly, fasten the mixing part and the closure part to the milk reservoir.
According to one embodiment of the invention, the locking part is annular and is movable in rotation relative to the closure part about an axis of rotation and between the release position and the locking position.
According to one embodiment of the invention, the locking part includes at least one fixing member, such as a fixing ramp, configured to cooperate with at least one fastening element, such as a fixing lug, configured to be secured in rotation with the mixing part, and for example provided on the mixing part or on the milk reservoir, the at least one fastening member being configured to cooperate with the at least one fastening element during a rotation of the locking part from the release position to the locking position so as to displace the locking part towards the mixing part, the locking part being configured to displace the closure part towards the mixing part during a rotation of the locking portion from the release position to the locking position.
According to one embodiment of the invention, the locking part includes a bearing face configured to displace the closure part towards the mixing part during a rotation of the locking part from the release position to the locking position.
According to one embodiment of the invention, the locking part and the closure part form a subassembly.
According to one embodiment of the invention, the milk frothing device includes an immobilization device configured to immobilize the mixing part in rotation with respect to the milk reservoir when the mixing part is received in the milk reservoir.
The present invention further concerns an automatic coffee machine including a hot water/vapor outlet nozzle, a boiler producing hot water and/or vapor to feed said hot water/vapor outlet nozzle, and a milk frothing device according to the present invention, the hot water/vapor inlet orifice of the milk frothing device being connected to the hot water/vapor outlet nozzle.
By automatic coffee machine, it should be understood that the coffee machine comprises in particular a brewing chamber which can be fed with ground coffee by a grain grinder incorporated in the machine, or a brewing chamber which can receive a coffee capsule or pod or a brewing chamber formed by a spoon intended to be filled with ground coffee and manually emptied.
The invention will be better understood using the following description with reference to the appended schematic drawings representing, as a non-limiting example, an embodiment of this milk frothing device.
The milk frothing device 2 includes a milk reservoir 4 delimiting an internal volume intended to contain milk and comprising an upper opening 5. The milk reservoir 4 can for example have a generally cylindrical shape, and have a circular traversable section. However, the milk reservoir 4 could also have a completely different shape, and for example have an oblong or even rectangular traversable section.
The milk frothing device 2 further includes a mixing part 6 arranged at the upper opening 5. The mixing part 6 more particularly includes a mixing body 7 provided with an upper face 8 which is generally planar. The mixing body 7 is configured to partially close the milk reservoir 4 and to be removable with respect to the milk reservoir 4. The mixing body 7 can for example include a tubular mounting portion 9 configured to be mounted in the milk reservoir 4, and more particularly to be inserted into the milk reservoir 4 via the upper opening 5 of the milk reservoir 4.
Advantageously, the milk frothing device 2 includes an immobilization device configured to immobilize the mixing body 7 in rotation with respect to the milk reservoir 4 when the tubular mounting portion 9 is received in the milk reservoir 4. The immobilization device can for example include immobilization ribs 11 provided on an upper peripheral edge of the milk reservoir 4 and distributed about a central axis of the milk reservoir 4, and immobilization grooves 12 provided on the mixing body 7 and configured to cooperate respectively with the immobilization ribs 11.
The mixing body 7 further includes a mixing chamber 13 which opens into the upper face 8 of the mixing body 7 and which is provided with an outlet orifice 14, and furthermore a main flow conduit 15 formed in the upper face 8 of the mixing body 7 and opening into the mixing chamber 13. According to the embodiment shown in the figures, the mixing chamber 13 is of the cyclonic type and extends vertically, and the main flow conduit 15 opens tangentially into the mixing chamber 13. Advantageously, the main flow conduit 15 opens into an upper part of the mixing chamber 13, and for example into a high point of the mixing chamber 13, and the outlet orifice 14 is located in a lower part of the mixing chamber 13, and is for example located at a low point of the mixing chamber 13.
As shown more particularly in
The mixing body 7 also includes a connection nozzle 17 configured to be connected to a hot water/vapor outlet nozzle of the automatic coffee machine 3, and more particularly to be fluidly connected to a boiler which equips the automatic coffee machine 3 and which is configured to produce hot water and/or vapor. Advantageously, the connection nozzle 17 extends radially with respect to a central axis of the mixing body 7, and is configured to extend radially with respect to the central axis of the milk reservoir 4.
The mixing body 7 further includes a hot water/vapor inlet orifice 21 which is fluidly connected to the connection nozzle 17 and which opens into the first conduit portion 15.1 and more particularly opposite the mixing chamber 13. The main flow conduit 15 is thus configured to fluidly connect the hot water/vapor inlet orifice 21 to the mixing chamber 13, and to allow a hot water/vapor flow in the main flow conduit 15 and up to the mixing chamber 13.
The milk frothing device 2 also includes a milk supply conduit 22 fluidly connected to the main flow conduit 15, and therefore configured to be fluidly connected to the mixing chamber 13 via the main flow conduit 15. According to the embodiment shown in the figures, the mixing part 6 includes the milk supply conduit 22, and more particularly the mixing body 7 and the milk supply conduit 22 are made in one piece.
As shown more particularly in
According to the embodiment shown in the figures, the mixing body 7 further includes an air intake channel 23 which is formed in the upper face 8 of the mixing body 7 and which opens into the main flow conduit 15 at the section restriction 16. The air intake channel 23 is thus configured to be fluidly connected to the mixing chamber 13 via the main flow conduit 15.
The previously described section restriction 16 induces an increase in the speed of the vapor flowing in the main flow conduit 15, which generates a vacuum in the milk supply conduit 22 and in the air intake channel 23. The section restriction 16 is therefore more particularly configured to form a milk and air suction system based on the Venturi effect. The main flow conduit 15 is thus configured so that a hot water/vapor flow in the main flow conduit 15 from the hot water/vapor inlet orifice 21 and up to the mixing chamber 13 generates a vacuum in the milk supply conduit 22 and a vacuum in the air intake channel 23 and consequently leads to a suction of milk and air in the main flow conduit 15 and a flow of milk and air sucked up to the mixing chamber 13. In addition, the second conduit portion 15.2, which has a flow cross section which increases in the direction of the mixing chamber 13, promotes a first mixing of vapor, milk and air respectively from the hot water/vapor inlet orifice 21, the milk supply conduit 22 and the air intake channel 23, before their arrival in the mixing chamber 13.
The mixing body 7 further includes a milk pouring conduit 24 fluidly connected to the outlet orifice 14 of the mixing chamber 13, and configured to allow hot milk and milk froth to be poured into a container, such as a cup, arranged vertically below the milk pouring conduit 24. Advantageously, the milk pouring conduit 24 is configured to extend radially with respect to the central axis of the milk reservoir 4.
As shown more particularly in
According to the embodiment shown in the figures, the seal 25 includes a seal body 25.1 entirely housed in the receiving groove 26, and a sealing lip 25.2 extending along the seal body 25.1 and projecting out of the receiving groove 26. Advantageously, the seal 25 is continuous and can for example have a constant cross-section.
The milk frothing device 2 includes in addition a closure part 27 configured to cover the mixing body 7 and to bear against the mixing body 7. The mixing body 7 may possibly include a bearing wall 7.1 which extends around the mixing chamber 13 and the main flow conduit 15 and which internally delimits the receiving groove 26, the bearing wall 7.1 projecting from the upper face 8 of the mixing body 7 and the closure part 27 then being configured to bear against an upper edge of the bearing wall 7.1.
As shown in
The mixing part 6 and the closure part 27 are configured to close the milk reservoir 4 and to be removable with respect to the milk reservoir 4. The mixing part 6 and the closure part 27 thus form a lid configured to close the milk reservoir 4.
According to the embodiment shown in the figures, the closure part 27 includes a filling opening 28 configured to be located opposite a passage opening 29 provided on the mixing body 7 and opening into the milk reservoir 4, and a flap 31 movable, and for example pivotally mounted, between an open position in which the flap 31 at least partially releases the filling opening 28 and enables an introduction of milk into the milk reservoir 4 and a closed position in which the flap 31 at least partially seals the filling opening 28.
The closure part 27 is more particularly movably mounted relative to the mixing part 6 between a closed position in which the closure part 27 closes the mixing chamber 13, the main flow conduit 15 and the air intake channel 23, and an open position in which the mixing chamber 13, the main flow conduit 15 and the air intake channel 23 are open and accessible for cleaning.
Advantageously, the milk frothing device 2 also includes a holding system 32 configured to hold the closure part 27 in the closed position and to ensure a compression of the seal 25 when the closure part 27 is in the closed position. The holding system 32 is more particularly configured to press the closure part 27 against the upper face 8 of the mixing body 7 when the closure part 27 is in the closed position, so as to compress the seal 25, and more particularly the sealing lip 25.2 of the seal 25. According to the embodiment shown in the figures, the holding system 32 is also configured to removably, that is to say temporarily and reversibly, fasten the mixing part 6 and the closure part 27 to the milk reservoir 4. However, such a fastening of the mixing part 6 and the closure part 27 to the milk reservoir 4 could be made by a connecting device separate from the holding system 32.
As shown in
According to the embodiment shown in the figures, the closure part 27 is configured to occupy an intermediate position located between the closed position and the open position and in which the closure part 27 rests on the sealing lip 25.2 of the seal 25 and is therefore located opposite the mixing chamber 13 and the main flow conduit 15 and is spaced apart from the mixing part 6, and the holding system 32 is configured to displace the closure part 27 from the intermediate position to the closed position and in the direction of the mixing part 6, and therefore to move the closure part 27 closer to the mixing part 6, when the locking part 33 is displaced from the release position to the locking position.
As shown in
Advantageously, the locking part 33 includes a bearing face 36 (see in particular
According to the embodiment shown in the figures, the locking part 33 is captively mounted on the closure part 27, so that the locking part 33 and the closure part 27 form a non-detachable subassembly.
As shown more particularly in
Advantageously, the holding system 32 is also configured to confer on the closure part 27 only one translational degree of freedom in a direction of translation D1, which is for example perpendicular to the junction area and therefore parallel to the axis of rotation A, when the closure part 27 is displaced between the intermediate position and the closed position. To this end, the holding system 32 includes a first guide member 39, such as a recessed guide member, and a second guide member 41, such as a projecting guide member, secured respectively to the mixing part 6 and the closure part 27 and configured to be slidably mounted one inside the other in the direction of translation D1.
The first and second guide members 39, 41 have complementary and non-circular cross-sections, and are configured to guide the closure part 27 in translation relative to the mixing part 6 and in the direction of translation D1 when the closure part 27 is displaced between the intermediate position and the closed position. According to the embodiment shown in the figures, the first guide member 39 delimits the passage opening 29 provided on the mixing body 7, and the second guide member 41 projects downwards from a lower face of the closure part 27 and is configured to be introduced into the passage opening 29. However, according to a variant of the invention, the first and second guide members 39, 41 could be laterally offset with respect to the filling opening 28 and the passage opening 29.
As shown more particularly in
According to the embodiment shown in the figures, the air flow rate adjustment device 43 includes a support part 44 fastened to the closure part 27 and projecting from an upper face of the closure part 27, and a flow rate adjustment member 45, such as a flow rate adjustment button, supported by the support part 44 and movably mounted, and for example movably mounted according to a helical movement, relative to the support part 44 in a direction of displacement D2 which can for example be substantially vertical when the milk frothing device 2 rests on a horizontal surface.
The flow rate adjustment member 45 and the support part 44 can for example extend coaxially with respect to each other, and the support part 44 can for example include two guide fingers 46 (see in particular
According to the embodiment shown in the figures, the flow rate adjustment member 45 includes an adjustment part 45.1 which is configured to cover the support part 44 and which includes an upper wall covering the support part 44 and a peripheral wall having a generally tubular shape and extending around the support part 44. As shown more particularly in
The flow rate adjustment member 45 is configured to occupy a plurality of adjustment positions offset from each other in the direction of displacement D2. Advantageously, the direction of displacement D2 is substantially parallel to the central axis of the milk reservoir 4 when the mixing part 6 is received in the milk reservoir 4 and the closure part 27 is in the closed position.
The air flow rate adjustment device 43 further includes a sealing element 48 which is annular and which is fastened to the flow rate adjustment member 45. According to the embodiment shown in the figures, the support part 44 includes a bearing surface 49, provided on an upper end face of the support part 44, which is annular and against which the sealing element 48 is capable of being compressed according to the position occupied by the flow rate adjustment member 45.
The sealing element 48 and the support part 44 are configured to delimit an air flow passage 51 (see
The flow rate adjustment member 45 is more particularly displaceable between a maximum adjustment position in which the flow cross section of the air flow passage 51 is maximum, and a minimum adjustment position in which the flow cross section of the air flow passage 51 is minimum, and for example zero or substantially zero.
As shown in
As shown more particularly in
According to the embodiment shown in the figures, the support part 44 includes an insertion hole 55, which can for example have a diameter greater than one millimeter and preferably greater than 1.5 millimeters, oriented substantially parallel to the direction of displacement D2, and the air flow rate adjustment device 43 includes a passage restriction member 56, such as a pin or a needle with a generally cylindrical shape, having a lower end portion which is housed in the insertion hole 55. The passage restriction member 56 is secured in movement to the flow rate adjustment member 45, and is therefore movably mounted in the insertion hole 55 in the direction of displacement D2. The passage restriction member 56 is elongated and extends in a direction of extension which is parallel to the direction of displacement D2. The insertion hole 55 and the passage restriction member 56 more particularly delimit the calibrated air passage 54, so that the calibrated air passage 54 is annular.
According to the embodiment shown in the figures, the support part 44 includes a cavity 57 which opens into the upper end face of the support part 44 and into which the insertion hole 55 opens. The cavity 57 and the flow rate adjustment member 45 delimit an internal chamber 58 configured to fluidly connect the air flow passage 51 to the insertion hole 55.
Of course, the present invention is in no way limited to the described and illustrated embodiment which has been given only as an example. Modifications are still possible, in particular with regards to the constitution of the various elements or by substitution with technical equivalents, yet without departing from the scope of protection of the invention.
Number | Date | Country | Kind |
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22/05745 | Jun 2022 | FR | national |