Method for producing an ordered array of interconnected acoustic microchannels

Abstract

A manufacturing method of an acoustic coating in an ordered array of interconnected micro-channels intended to receive, on a reception surface, an incident acoustic wave with direction Ac normal to this surface, the method including depositing a sacrificial material on a substrate surface to form a three-dimensional scaffold of filaments, infiltrating at least one part of the three-dimensional scaffold with a thermosetting material, solidifying the thermosetting material to form a solidified material, and removing the sacrificial material from the solidified material to form the ordered array of interconnected micro-channels, the filaments forming by superimposed layers the three-dimensional scaffold being, for a given layer of filaments, oriented in a direction forming, in a plane formed by the layer, a first angle θ relative to the direction Ac of the incident acoustic wave, to confer acoustic properties to the ordered array of interconnected micro-channels and thus form the acoustic coating.

Claims

1. A manufacturing method of an acoustic coating in an ordered array of interconnected micro-channels intended to receive, on a reception surface, an incident acoustic wave with a direction normal to the reception surface, the method comprising: depositing a sacrificial material on a substrate surface to form a three-dimensional scaffold of filaments, infiltrating at least one part of said three-dimensional scaffold with a thermosetting material, solidifying said thermosetting material to form a solidified material, and removing said sacrificial material from said solidified material to form said ordered array of interconnected micro-channels, wherein, to confer acoustic properties to said ordered array of interconnected micro-channels and form said acoustic coating, said filaments forming by superimposed layers said three-dimensional scaffold are, for a given layer of filaments, oriented in a direction forming, in a plane formed by said layer, a first predetermined angle relative to the direction of said incident acoustic wave, and wherein a diameter or a cross-section width of the filaments is less than 250 microns.

2. The manufacturing method according to claim 1, wherein said filaments have a different diameter or cross-section width depending on the orientation direction of said filaments in said three-dimensional scaffold.

3. The manufacturing method according to claim 1, wherein said superimposed layers forming said three-dimensional scaffold include filaments oriented, for some, according to the first predetermined angle and, for others, according to a second angle being a negative value of the first predetermined angle, a layer of filaments oriented according to the first predetermined angle following a layer of filaments oriented according to said second angle.

4. The manufacturing method according to claim 1, wherein said first predetermined angle is comprised between 25° and 40.

5. The manufacturing method according to claim 1, wherein the fill rate of said three-dimensional scaffold is at least 70%.

6. The manufacturing method according to claim 1, wherein said sacrificial material is an organic ink or a natural wax.

7. The manufacturing method according to claim 1, wherein said thermosetting material is a polymer resin.

8. The manufacturing method according to claim 7, wherein said polymer resin is a photo-polymerizing resin.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other features and advantages of the present invention will be revealed by the detailed description given below, with reference to the following figures free of any limiting character and in which:

(2) FIG. 1A illustrates, in exploded perspective, a first example of assembly of a three-dimensional scaffold of filaments conforming with the invention,

(3) FIG. 1B illustrates in exploded perspective a second example of assembly of a three-dimensional scaffold of filaments conforming with the invention,

(4) FIG. 2 is a view of the three-dimensional scaffold of FIG. 1 once assembled,

(5) FIG. 3 is a view of the ordered array of interconnected acoustic micro-channels obtained from the three-dimensional scaffold of FIG. 2, and

(6) FIG. 4 shows an example of an acoustic coating including the array of FIG. 3.

DETAILED DESCRIPTION OF THE INVENTION

(7) FIG. 1A illustrates in exploded perspective one part of a three-dimensional scaffold 10 of filaments 100, 200, 300, advantageously cylindrical, of a sacrificial material allowing, in conformity with the invention, the production of an ordered array of interconnected acoustic micro-channels of a nature to confer acoustic properties to a wall intended to receive on one reception surface an incident acoustic wave with direction Ac normal to this surface. This wall is preferably, without this being limiting, a wall of a turbomachine such as an airplane turbojet.

(8) The manufacturing of an ordered array of interconnected micro-channels is carried out by additive manufacturing using the method described in the application cited in the preamble and to which it is advisable to refer for ampler details. This method allows depositing, by means of a suitable print head, cylindrical filaments of a sacrificial material with diameters of less than 1000 μm along a path specified by the user. By gravity pouring, the three-dimensional scaffold of sacrificial material is then impregnated with a thermosetting material. Once the thermosetting material is solidified, the product obtained is heated to a temperature greater than the melting temperature (typically greater than 60°) of the sacrificial material to cause it to melt and thus reveal the ordered array of micro-channels, with the size and the shape of the cylindrical filaments of the sacrificial material in the solidified material obtained. Interconnections between the micro-channels exist regularly at the points of contact between the filaments during superposition of the different layers of the sacrificial material intended to generate these micro-channels. In the final analysis, therefore, it is a mold produced by additive manufacturing.

(9) In conformity with the invention, to confer acoustic properties to the ordered array of interconnected micro-channels obtained by this method, the filaments 100, 200, 300 which form the three-dimensional scaffold 10 by superimposed layers are oriented, during their successive deposition on a substrate 12 and at a given layer, according to an orientation direction forming in space (the two straight lines not being coplanar but located in parallel planes) a predetermined angle θ relative to the direction Ac of the incident acoustic wave impacting perpendicularly the reception surface. Thus, a first layer of filaments 100 having a direction inclined on the order of 30° (typically 32°) relative to this direction of the acoustic wave is followed by a second layer 200 having an inclination on the order of 0° (hence a direction assumed to be parallel to the incident acoustic wave Ac) then a third layer 300 having a direction inclined typically by −32° (the same value as the initial inclination, but with the opposite sign) relative to the direction of the incident acoustic wave. The deposit of the following superimposed layers continues until the deposition of the last layer, in the same succession of layers of filaments 100, 200, 300 and therefore the same different orientations.

(10) The aforementioned angle of inclination of 32° is not intended to be limiting, and the inventors have been able to observe that an angle θ comprised between 25° and 40° would allow obtaining satisfactory acoustic properties.

(11) Likewise, FIG. 1B illustrates a different three-dimensional scaffold of filaments in which a layer of filaments 100 oriented in the horizontal plane formed by this layer at an angle on the order of 30° relative to the direction Ac of the incident acoustic wave is followed by a layer of filaments 300 oriented according to an opposite angle on the order of −30° relative to the same direction Ac of the incident acoustic wave.

(12) It can be noted that if the filaments, when they are cylindrical, advantageously have the same diameter, a different diameter depending on the orientation direction in the three-dimensional scaffold can however be considered. The same is true when these filaments have a non-circular, elliptical for example, cross section.

(13) FIG. 2 shows the three-dimensional scaffold 10 obtained once the superimposed layers of filaments deposited successively from the substrate 12 and which will be impregnated with thermosetting material 14. The diameter or the width of the cross section of the filaments is preferably selected less than 250 microns and the fill rate of the three-dimensional scaffold is selected so that it is at least 70%.

(14) The final structure illustrated in FIG. 3 after removal of the sacrificial material (an actual example of a turbomachine wall acoustic coating 20 obtained by the method of the invention is illustrated in FIG. 4) therefore has interconnected micro-channels of constant cross section (This interconnection resulting, as previously stated from the points of contact between the sacrificial filaments) which form a porous array 18 within which the acoustic wave will be able to propagate and attenuate by interacting with the rigid skeleton 16 formed by the thermosetting material. The microstructure is directly controlled by the printing of the sacrificial material by additive manufacturing. The rigid skeleton, for its part, allow giving greatly superior mechanical strength properties to those encountered for example with current stochastic foams available commercially as acoustic coatings. Moreover, the rigid skeleton being constituted of a thermosetting material, it therefore possesses great chemical stability, which is an asset in the case of installation in zones subjected to different aggressive chemical agents as is the case in an airplane turbojet. Finally, the porous nature of the material causes a reduction of mass of the acoustic coating and therefore a reduction in cost, particularly by a reduction in energy consumption and an increase in useful load.

(15) The sacrificial material is advantageously an organic ink or a natural wax which must be formable by rapidly printing with small filament cross section diameters or widths (typically less than 250 microns), the removal of which must simple and at a temperature that does not degrade the thermosetting material. A material including a Prussian blue paste such as Loctite™ or a two-component material formed from a microcrystalline wax (type SP18) and a low molecular weight petroleum derivative such as Vaseline™ is preferred.

(16) The thermosetting material must have absorbent behavior and in particular good infiltration capacity (low viscosity) to impregnate perfectly, typically by gravity, the scaffold while respecting its geometry, and sufficient mechanical strength to support the elimination of the sacrificial material without degradation. It must also be only slightly exothermic so that the heat released during its solidification does not cause the sacrificial material to melt. A material based on polymer resin such as epoxy, or a photo-polymerizing resin, the latter allowing samples of larger dimensions to be obtained, is therefore completely suitable.