Coanda effect flow booster and aeraulic device comprising such a flow booster

1 . A Coanda effect flow amplifier for bringing about an amplified gas flow, comprising: a main air circulation duct, at least one injection orifice opening into the main duct, a plurality of orifices for feeding compressed driving gas, each being configured to be connected to a source of compressed driving gas in order to feed said at least one injection orifice with compressed driving gas, at least one distribution duct connecting said plurality of feed orifices to said at least one injection orifice, an amplification profile at least partially delimiting said at least one injection orifice and forming a convex surface configured to bring about a Coanda effect in a flow of compressed driving gas injected through said at least one injection orifice. 2 . The flow amplifier as claimed in claim 1 , wherein the main air circulation duct extends along a circulation axis, said at least one distribution duct forming an annular distribution cavity extending along and around the circulation axis, said at least one injection orifice forming a slot extending at least partially around the circulation axis. 3 . The flow amplifier as claimed in claim 2 , wherein a radial dimension of the slot is limited by the presence of a connecting radius exhibited by a deflecting wall facing each of the feed orifices, this deflecting wall being adjacent to the slot opening onto the injection orifice. 4 . The flow amplifier as claimed in claim 2 or 3 , wherein said at least one injection orifice is formed by an annular injection cavity extending around the circulation axis and radially with respect to this circulation axis. 5 . The flow amplifier as claimed in claim 2 , wherein the feed orifices are oriented transversely to the circulation axis, the flow amplifier also comprising at least one deflecting wall facing each of the feed orifices. 6 . The flow amplifier as claimed in claim 1 , comprising a plurality of mutually independent distribution ducts and a plurality of injection orifices, each distribution duct extending between at least one of the plurality of feed orifices and at least one of the plurality of injection orifices so that it is possible to inject separate flows of compressed driving gas through the plurality of injection orifices. 7 . The flow amplifier as claimed in claim 6 , wherein said at least one injection orifice is formed by an annular injection cavity extending around the circulation axis and radially with respect to this circulation axis, wherein said plurality of distribution ducts is formed by the annular distribution cavity, the flow amplifier also comprising at least two partition elements ( 52 ) for compartmentalizing the distribution cavity so as to form at least two independent distribution ducts. 8 . The flow amplifier as claimed in claim 1 , further comprising means for adjusting a flow cross section for the driving gas of said at least one injection orifice so as to regulate the flow rate of driving gas passing through said at least one injection orifice. 9 . The flow amplifier as claimed in claim 6 , further comprising means for adjusting a flow cross section for the driving gas of said at least one injection orifice so as to regulate the flow rate of driving gas passing through said at least one injection orifice, and wherein the adjusting means are configured to separately adjust the flow cross section for driving gas of at least two injection orifices communicating with independent distribution ducts so that it is possible to inject flows of compressed driving gas with different flow rates through said at least two orifices. 10 . The flow amplifier as claimed in claim 1 , wherein the plurality of injection orifices comprises at least one first and at least one second injection orifice, which are intended to be disposed respectively in the lower part and in the upper part of the main air circulation duct so that it is possible to bring about a different amplified air flow rate in the lower and upper parts. 11 . The flow amplifier as claimed in claim 1 , wherein the adjusting means are configured to separately adjust the flow cross section for driving gas of at least four injection orifices communicating with independent distribution ducts, the plurality of injection orifices also comprising at least one third and at least one fourth injection orifice, which are intended to be disposed respectively at opposite lateral parts of the main air circulation duct. 12 . The flow amplifier as claimed in claim 1 , comprising: a body in which said main air circulation duct, the plurality of feed orifices, said at least one distribution duct, the amplification profile and a first portion of said at least one injection orifice are formed, an injection ring forming a second portion of said at least one injection orifice, the injection ring being configured to be disposed facing the body, the first and second portions of said at least one injection orifice facing one another, the distance between the first and second portions of said at least one injection orifice defining a flow cross section for driving gas through said at least one injection orifice. 13 . The flow amplifier as claimed in claim 1 , further comprising means for adjusting a flow cross section for the driving gas of said at least one injection orifice so as to regulate the flow rate of driving gas passing through said at least one injection orifice, and wherein the adjusting means are configured to adjust the distance between the injection ring and the body so as to vary the flow cross section for driving gas of said at least one injection orifice. 14 . The flow amplifier as claimed in claim 1 , wherein the ring is movable with respect to the body about at least one axis transverse to a circulation axis of the main circulation duct, the adjusting means being configured to adjust the inclination angle of the ring with respect to said at least one transverse axis so as to vary the flow cross section for driving gas of said at least one injection orifice asymmetrically. 15 . An aeraulic apparatus for pollinating at least one receiver plant with pollen collected from at least one donor plant, comprising: a member for collecting the pollen from said at least one donor plant, a member for diffusing the pollen over at least one receiver plant, a channel for conveying the pollen collected from the collecting member to the diffusing member or members, and at least one flow amplifier as claimed in claim 1 . 16 . The use of a flow amplifier as claimed in claim 1 to amplify an air flow comprising particles exhibiting a predetermined sedimentation rate, wherein the Coanda effect flow amplifier brings about an air flow inside the main circulation duct, the speed of which is higher than the predetermined sedimentation rate. 17 . The use as claimed in claim 16 , wherein the speed of the air flow brought about inside the main circulation duct is less than or equal to 10 m·s −1 . 18 . The use as claimed in claim 17 , wherein the speed of the air flow brought about inside the main circulation duct is less than or equal to 5 m·s −1 .