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WO2025174452A1 - Matériaux d'atténuation phonique imprimés en 3d - Google Patents

Matériaux d'atténuation phonique imprimés en 3d

Info

Publication number
WO2025174452A1
WO2025174452A1 PCT/US2024/060070 US2024060070W WO2025174452A1 WO 2025174452 A1 WO2025174452 A1 WO 2025174452A1 US 2024060070 W US2024060070 W US 2024060070W WO 2025174452 A1 WO2025174452 A1 WO 2025174452A1
Authority
WO
WIPO (PCT)
Prior art keywords
sound dampening
sound
infill
coreactive
boundary
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
PCT/US2024/060070
Other languages
English (en)
Inventor
Jacob Michael KUPAS
Bret Michael BOYLE
Cynthia Kutchko
Ion Pelinescu
Zachary Phillip THOMPSON
Elizabeth Marie TEMSICK
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
PPG Industries Ohio Inc
Original Assignee
PPG Industries Ohio Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by PPG Industries Ohio Inc filed Critical PPG Industries Ohio Inc
Publication of WO2025174452A1 publication Critical patent/WO2025174452A1/fr
Pending legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/10Processes of additive manufacturing
    • B29C64/106Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/30Auxiliary operations or equipment
    • B29C64/307Handling of material to be used in additive manufacturing
    • B29C64/321Feeding
    • B29C64/336Feeding of two or more materials
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/40Structures for supporting 3D objects during manufacture and intended to be sacrificed after completion thereof
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y10/00Processes of additive manufacturing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y80/00Products made by additive manufacturing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60RVEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
    • B60R13/00Elements for body-finishing, identifying, or decorating; Arrangements or adaptations for advertising purposes
    • B60R13/08Insulating elements, e.g. for sound insulation
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B64AIRCRAFT; AVIATION; COSMONAUTICS
    • B64CAEROPLANES; HELICOPTERS
    • B64C1/00Fuselages; Constructional features common to fuselages, wings, stabilising surfaces or the like
    • B64C1/40Sound or heat insulation, e.g. using insulation blankets
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02BINTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
    • F02B77/00Component parts, details or accessories, not otherwise provided for
    • F02B77/11Thermal or acoustic insulation
    • F02B77/13Acoustic insulation
    • GPHYSICS
    • G10MUSICAL INSTRUMENTS; ACOUSTICS
    • G10KSOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
    • G10K11/00Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
    • G10K11/16Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
    • G10K11/162Selection of materials
    • G10K11/168Plural layers of different materials, e.g. sandwiches
    • GPHYSICS
    • G10MUSICAL INSTRUMENTS; ACOUSTICS
    • G10KSOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
    • G10K11/00Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
    • G10K11/16Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
    • G10K11/172Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using resonance effects
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29KINDEXING SCHEME ASSOCIATED WITH SUBCLASSES B29B, B29C OR B29D, RELATING TO MOULDING MATERIALS OR TO MATERIALS FOR MOULDS, REINFORCEMENTS, FILLERS OR PREFORMED PARTS, e.g. INSERTS
    • B29K2995/00Properties of moulding materials, reinforcements, fillers, preformed parts or moulds
    • B29K2995/0001Properties of moulding materials, reinforcements, fillers, preformed parts or moulds having particular acoustical properties
    • B29K2995/0002Properties of moulding materials, reinforcements, fillers, preformed parts or moulds having particular acoustical properties insulating
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29LINDEXING SCHEME ASSOCIATED WITH SUBCLASS B29C, RELATING TO PARTICULAR ARTICLES
    • B29L2024/00Articles with hollow walls
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29LINDEXING SCHEME ASSOCIATED WITH SUBCLASS B29C, RELATING TO PARTICULAR ARTICLES
    • B29L2024/00Articles with hollow walls
    • B29L2024/003Articles with hollow walls comprising corrugated cores
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29LINDEXING SCHEME ASSOCIATED WITH SUBCLASS B29C, RELATING TO PARTICULAR ARTICLES
    • B29L2024/00Articles with hollow walls
    • B29L2024/006Articles with hollow walls multi-channelled

Definitions

  • the present disclosure relates to 3D printed sound dampening materials for noise reduction, and methods for making and using the same.
  • a variety of industries such as aircraft, aircraft engines, audio equipment, mining, agriculture, automotive, household appliances, heating ventilation and air conditioning, and the like involve noise generation at a broad range of audible frequencies. Since these applications involve close proximity to humans, sound-dampening materials are desired because exposure to high noise levels may contribute to hearing loss, increased stress, difficulty communicating, and/or tiredness.
  • an additively manufactured sound dampening part comprising a boundary element comprising a first coreactive composition and an infill element comprising a second coreactive composition, wherein the boundary element substantially encloses the infill element, and the sound dampening part provides a sound transmission loss of at least 30 dB(A) for a 125Hz to 8kHz sound passing through the sound dampening part.
  • Another embodiment disclosed herein is a method of additively manufacturing a sound dampening part comprising depositing a boundary element in a first geometric configuration, the boundary element imparting a first sound dampening effect to the sound dampening part and depositing an infill element in a second geometric configuration different from the first geometric configuration, the infill element imparting a second sound dampening effect to the sound dampening part different from the first sound dampening effect, and wherein the boundary element and the infill element react and cure under ambient conditions to form the sound dampening part.
  • a multi-layer sound dampening part comprising a first sound dampening component comprising a boundary element comprising a plurality of internal structures each comprising a void, an infill element configured within the voids of the plurality of internal structures, and optionally, a structural element upon which the boundary element and the infill element are formed, wherein the boundary element, the infill element, and the optional structural element react and cure under ambient conditions to form the first sound dampening component.
  • the multi-layer sound dampening part may further comprise a second sound dampening component comprising a boundary element comprising a plurality of internal structures each comprising a void, an infill element configured within the voids of the plurality of internal structures, and optionally, a structural element upon which the boundary element and the infill element are formed, wherein the boundary element, the infill element, and the optional structural element react and cure under ambient conditions to form the second sound dampening component, wherein the first sound dampening component comprises a first layer of the multi-layer sound dampening part and the second sound dampening component comprises a second layer of the multi-layer sound dampening part, the first sound dampening element imparting a first sound dampening effect to the multi-layer sound dampening part and the second sound dampening component imparting a second sound dampening effect to the multi-layer sound dampening part different from the first sound dampening effect.
  • a second sound dampening component comprising a boundary element comprising a plurality of internal structures each compris
  • FIG. 1A illustrates a first exemplary embodiment of a sound dampening part.
  • FIG IB illustrates a second exemplary embodiment of a sound dampening part without a structural element.
  • FIG. 2A illustrates a third exemplary embodiment of a sound dampening part manufactured onto an optional substrate.
  • FIG. 2B illustrates a fourth exemplary embodiment of a sound dampening part without a structural element, manufactured onto an optional substrate.
  • FIG. 3 illustrates an exemplary embodiment of a multi-layer sound dampening part.
  • any numerical range recited herein is intended to include all sub-ranges subsumed therein.
  • a range of " 1 to 10" is intended to include all sub-ranges from (and including) the recited minimum value of 1 to the recited maximum value of 10, that is, having a minimum value equal to or greater than 1 and a maximum value of equal to or less than 10.
  • the use of the singular includes the plural and plural encompasses singular, unless specifically stated otherwise.
  • the use of "or” means “and/or” unless specifically stated otherwise, even though “and/or” may be explicitly used in certain instances.
  • Ambient conditions or “room temperature” are used herein to describes temperature values as low as 20 °C, 23 °C, or 25 °C, as high as 27 °C, 29 °C, or 30 °C, or between any of the foregoing values used as endpoints, such as between 20 °C and 30 °C , or 23 C and 27 °C; pressure values as low as 0.85 atm, 0.90 atm, or as high as 1.0 atm, 1.02 atm, or 1.05 atm, or between any of the foregoing values used as endpoints, such as between 0.85 atm and 1.05 atm, or 0.95 atm and 1.05 atm; and relative humidity values as low as 25% RH, 35% RH or 50% RH, as high as 75% RH, 85% RH, 90% RH, or 95% RH, or between any of the foregoing values used as endpoints, such as between 25% RH and 95% RH or between 50% RH and 75% RH.
  • Coreactive composition refers to the reaction product produced from the chemical interaction and reaction between at least two coreactive components (e.g., a first coreactive component, a second coreactive component, etc.).
  • Coreactive component refers to a compound containing at least one reactive functional group, that when physically combined with a second reactive functional group, interacts and reacts with the second reactive functional group to form a coreactive composition.
  • Additive manufacturing using coreactive compositions typically utilizes at least two components that react with each other (that is, are coreactive).
  • a first coreactive component sometimes referred to herein as a first reactant group, a first reactive functional group, part A
  • at least one second coreactive component sometimes referred to herein as a second reactant group, second reactive functional group, part B
  • the coreactive composition may thereafter cure under ambient conditions or, depending on the chemistry of the reaction, with the assistance of, for example, heat, actinic radiation, catalysts, addition of curing agents-post extrusion, etc.
  • thermosetting polymer sometimes referred to as a thermoset
  • thermoplastic polymer or combinations thereof.
  • At least the first coreactive component and the second coreactive component are chosen by one skilled in the art to result in the desired final product (e.g., thermoset, thermoplastic, etc.).
  • each layer of the deposited coreactive composition it may be desirable to select the chemistry of each layer of the deposited coreactive composition such that covalent bonds between successive layers are formed.
  • Different portions of the article can be additively manufactured from different coreactive compositions (e.g., a first coreactive composition printed to form a first portion of the article such as a base portion, an internal structure, etc., and a second coreactive composition printed to form a second portion of the article), and, depending on the chemical reactivity between the different coreactive compositions, covalent bonds might also form between different materials.
  • An article may be additively manufactured so as to have a rigid portion and a flexible portion, a rigid portion and a foam-like portion, a tactile portion and a rigid and/or flexible portion, two or more portions comprising different densities, one or more conductive portions, one or more thermally/electrically conductive portions, two or more different colors, two or more different rheological profiles, two or more different materials comprising different affinities for water and/or solvent(s), and the like.
  • the article may also be printed such that the coreactive compositions are deposited onto existing articles (e.g., other thermosets and/or thermoplastics, metals, woods, composite materials, ceramics, etc.) resulting in an article comprising both coreactive and non-coreactive compositions.
  • Additive manufacturing as described herein may result in an article having higher strength, particularly along the Z (e.g., vertical) axis, as compared to other extruded or printed parts due to the covalent bonding between the printed layers.
  • Strong intralayer and interlayer covalent bonding results in not only stronger parts, but also in more uniform part geometries; that is, less print lines and/or portion differentials.
  • the ability to form, in one process, articles having multiple substrates and/or portions comprising different coreactive or non-coreactive compositions is a further advantage.
  • Table 1 describes suitable coreactive compositions and the coreactive components from which they can be formed. These coreactive compositions can be printed by any of the methods described herein, either alone or in combination, to form three dimensional articles.
  • the coreactive compositions can be additive manufactured at relatively low viscosity (“ viscosity” may refer to a value determined at 25 °C and ambient pressure, and reflects a fluid’s resistance to flow when subjected to a shear stress and/or a shear strain). Therefore, relatively large amounts (e.g., high relative weight percent) of additives and/or fillers can be included with the coreactive components while maintaining a printable viscosity. Both the type and/or the amount of additives can be selected or “tuned” to result in desirable chemical and/or physical properties of the printed article.
  • Coreactive compositions can be tuned with the addition of additives and/or fillers for desired mechanical performance (e.g., strength, elasticity, rigidity, sag resistance, etc.), surface features (e.g., hardness, texturing, smoothness, etc.), chemical resistance (e.g., solvent resistance, etc.), thermal resistance (including fire retardancy, etc.) or conductivity, and/or electrical insulation or conductivity.
  • Coreactive compositions can also be tuned with the addition of one or more catalytic/activator/accelerant additives in any of the coreactive components to result in desirable reaction kinetics, such as rate of reaction.
  • Table 2 describes additives that can be included with any coreactive compositions, such as those described in Table 1.
  • the additives can be included in either or both of the first and second coreactive components depending on the desired chemical and/or physical properties of the resulting article.
  • Table 2 describes specific additives and fillers that may be suitable for ambient reactive extrusion-based three-dimensional printing, however, Table 2 is non-limiting. Therefore, other additives may be included with the coreactive composition(s), such as additives known to those skilled in the coatings, extrusion, and thermoplastic areas.
  • any suitable combination of coreactive composition(s) and optionally additive(s)/filler(s), can be printed by a three-dimensional printing system adapted for mixing and extruding feedstocks.
  • Two or more volumetric metering pumps e.g., positive displacement pumps, progressive cavity pumps, etc.
  • the mixing volume can include mechanical (e.g., driven) mixing features.
  • the first and second coreactive components Upon entering the mixing volume, the first and second coreactive components begin to mix and react, and thereafter, are extruded through an extrusion print nozzle in an at least partially reacted state. Once extruded, the two coreactive components further react and cure, which, as described above, may be under ambient conditions, to form either a thermoset, a thermoplastic material, or combinations thereof.
  • the present disclosure relates to sound dampening part(s) additively manufactured (e.g., 3D printed) from ambiently -cured coreactive compositions, such as those described in Section II.
  • the physical and/or chemical characteristics of the sound dampening parts may be tuned and/or optimized to result in a targeted overall sound dampening effect. That is, each element of the sound dampening part, to be described in further detail herein, may be formed from coreactive compositions which are tuned/optimized to impart sound dampening properties to each element, resulting in an overall sound dampening effect of the sound dampening part.
  • the sound dampening part may be printed in-place, such as additively manufactured onto an existing structure/substrate, or additively manufactured and applied to the structural component/substrate thereafter (e.g., applied in place).
  • Multi-layer sound dampening parts can also be additively manufactured to dampen sound across a wide range of frequencies.
  • Sound dampening parts find applications in a wide variety of industries including the automotive industry (e.g., sound dampening structures applied to engine bays, fire walls, wheel wells, and/or interior structures of the vehicle), the aerospace industry (e.g., sound dampening structures applied to the walls of the cabins and/or cockpits of an aircraft), the consumer goods industry (e.g., the housings of dishwashers, washers, dryers, and/or other consumer goods that benefit from noise/ vibration reduction) and the architectural industry (e.g., sound dampening structures applied to the interior or exterior of walls and/or room partitions).
  • automotive industry e.g., sound dampening structures applied to engine bays, fire walls, wheel wells, and/or interior structures of the vehicle
  • the aerospace industry e.g., sound dampening structures applied to the walls of the cabins and/or cockpits of an aircraft
  • the consumer goods industry e.g., the housings of dishwashers, washers, dryers, and/or other consumer goods that benefit from noise/ vibration
  • the sound dampening parts can be additively manufactured such that any one of an overall sound dampening effect (e.g., dampening of one or more desired frequencies of sound), weight, and/or size of the sound dampening part are targeted and/or optimized, which can be in combination, to achieve a desired effect.
  • any one of the weight and size may be optimized, either alone or in combination, to result in the smallest and lightest part that imparts the targeted noise reduction for a given frequency band.
  • FIG.s 1A and IB depict illustrative embodiments of sound dampening parts 101 and 102, that although shown as comprising a certain rectangular geometry, may be additively manufactured into any desired shape. Therefore, FIGs 1A and IB are meant to be illustrative only, and not to limit the size, shape, geometry, or position of the sound dampening part(s). Furthermore, it should be appreciated that for like elements, the same reference numbering is used, which may be designated as A, B, C in some contexts.
  • Sound dampening part 101 may comprise three basic elements: a structural element 105 which may serve as a base structure of sound dampening part 101; a boundary element 110 additively manufactured atop a surface of the structural element 105 and including one or more internal structures 112 and perimeter 114; and an infill material 115 additively manufactured, or otherwise applied inside the voids of the internal structures 112 of boundary element 110.
  • a first coreactive composition such as a Michael addition-based coreactive composition as described in Section I previously, may be additively manufactured as a structural element 105.
  • the structural element 105 may serve as a base structural layer, upon which one or more additional elements of the sound dampening part 101 is/are built.
  • Structural element 105 may impart a first sound dampening effect, such as a vibration dampening (e.g., sound blocking) effect to sound dampening part 101.
  • a second coreactive composition such as a polyurea-based coreactive composition, may be additively manufactured as boundary element 110 onto an upper surface of structural element 105.
  • Boundary element 105 may form the perimeter of the sound dampening part 101 (e.g., the side walls/ exterior boundary) and may also include one or more internal structures 112. Internal structures 112 may be formed as substantially or completely hollow structures which comprise a predetermined structural size and shape (e.g., a cellular structure, a lattice structure, etc.). Boundary element 110 may impart a second sound dampening effect to the sound dampening part 101, such as a sound blocking/deadening effect. Boundary element 110 may also provide additional structural support and rigidity to the sound dampening part.
  • a third coreactive composition such as a polyurethane-based coreactive composition may be additively manufactured, or otherwise infilled into the voids of the one or more internal structures 112 of boundary element 110, forming infill material 115.
  • Infill material 115 may comprise a foam-like material imparting a third sound dampening effect, such as a sound absorbing effect to sound dampening part 101.
  • the physical and/or chemical characteristics of, such as the thickness of, size of, geometry of, composition of, and relative proportions of (or any combination of the foregoing of) structural element 105, boundary element 110, and infill material 115 can be tuned or otherwise adjusted, either alone or in combination, such that a small, thin sound dampening part is formed with high sound blocking/absorbing characteristics for a given frequency range.
  • any of the physical and/or chemical properties of any of the elements of sound dampening part 101 in order for the overall thickness of the sound dampening part 101 to comprise less than 5 inches in thickness, such as in the 0.1 inch to 5 inch range, and more particularly in the 0.25 inch to 2 inch range, and more particularly in the 0.25 inch to 1 inch range.
  • the physical and/or chemical properties of any of the elements of sound dampening part 101 can be designed, tuned, or adjusted, either alone or in combination, to provide a sound absorbing and/or dampening effect in the form of a sound transmission loss for sound waves passing through sound dampening part 101.
  • the sound may have a frequency of 125Hz to 8kHz and the sound transmission loss may be as low as 10 db(A), 15 db(A), 20 db(A), 25 db(A), 30 db(A), 35 db(A), or as high as 40 db(A), 45 db(A), 50 db(A), 55 db(A), 60 db(A), 65 db(A), 70 db(A), or within any range encompassed by any two of the foregoing values as endpoints.
  • the sound transmission loss may be from 10 db(A) to 70 db(A), from 15 db(A) to 65 db(A), from 20 db(A) to 60 db(A), from 25 db(A) to 55 db(A), from 30 db(A) to 50 db(A), or from 35 db(A) to 45 db(A).
  • multiple layers of sound dampening part(s) 101 can be formed in successive layers, as illustrated in FIG. 3, where each layer targets sound reduction for a given frequency band/range (which may be different frequency bands/ranges).
  • the resulting multi-layer sound dampening part can absorb and/or block sound over a wider frequency range than a single-layer sound dampening part.
  • the coreactive compositions may be reactive with one another at ambient conditions (e.g., ambient pressure and temperature). Curing of the coreactive composition may also occur under similar ambient conditions. In any of the foregoing cases, curing of the co-reactive components may be accomplished in the absence of special condition(s) such as UV light, heat, catalysts, or chemical initiators required to promote the curing process. a. Structural Element of the Sound Dampening Part
  • Sound dampening part 101 can include structural element 105.
  • Structural element 105 can be a rigid or semi-rigid structural element 105 upon which the additional elements of sound dampening part 101 are formed.
  • ARE type three-dimensional printing technology as described in Section II, allows for covalent bonding to form between successive layers of coreactive compositions deposited atop one another.
  • structural element 110 and/or infill element 115 may be applied to structural element 105 during the additive manufacturing process, and covalent bonding can form between elements, resulting in a congruent object that cures substantially at the same time.
  • structural element 105 may be additively manufactured from a first coreactive composition, such as an Michael addition-based coreactive composition, and particularly, an Aza-Michael addition based coreactive composition.
  • a first coreactive composition such as an Michael addition-based coreactive composition, and particularly, an Aza-Michael addition based coreactive composition.
  • the Aza-Michael addition-based coreactive composition chemistry may be advantageous for the composition of structural element 105 due to the vibration dampening effect of Aza-Michael additionbased coreactive compositions.
  • structural element 105 may be additively manufactured from any other coreactive composition described in Section I, as based upon a desired effect (e.g., sound blocking characteristics, flexibility, rigidity, etc.).
  • Structural element 105 may be designed to have suitable rigidity to support additional elements of sound dampening part 101, while minimizing the thickness of the structural element 105 to save on mass (e.g., avoiding an unnecessarily heavy structural element 105, contributing to a higher-weight sound dampening part 101). However, in some cases, structural element 105 may be absent (e.g., FIG. 2B), such as if a light and thin part is desired (e.g., removing structural element 105 may result in a lighter acoustically damping part 101).
  • Structural element 105 may have a relatively higher flexural modulus than the other elements of sound dampening part 101, as measured by a flexural test such as ISO 178, such as between 2358 Mpa and 1552 MPa.
  • structural element 105 contributes to vibration dampening and acts as a sound blocking portion of sound dampening part 101.
  • structural element 105 may block sound in the 100 Hz and 9000 Hz (i.e., 9kHz) range frequency range.
  • the dimensions and composition of structural element 105 can be adjusted, either alone or in combination with the other elements of the sound dampening part 101, to achieve the desired sound dampening performance for each application.
  • the thickness of structural element 105 may be adjusted in order for the overall thickness of the sound dampening part 101 to comprise less than 5 inches in thickness, such as in the 0.1 inch to 5 inch range, and more particularly in the 0.25 inch to 2 inch range, and still more particularly in the 0.25 inch to 1 inch range.
  • structural element 105 can be additively manufactured into any suitable shape, which can include irregular exterior boundaries, and/or non-planar surfaces.
  • structural element 105 is an optional element of sound dampening part 101, which may or may not be present in different embodiments of the present invention.
  • structural element 105 may not be present (e.g., is not necessary to provide structural rigidity).
  • structural element 105 may not be present to save weight.
  • the additive manufacturing process may utilize a secondary substrate, upon which the additional element (e.g., boundary element 110 and/or infill material 115) are applied and/or printed, and the secondary substrate may be removed/discarded (e.g., similar to support materials utilized in traditional three-dimensional printing) such that structural element 105 is not a required base component of the sound dampening part 101, as will be described in further detail with reference to FIG 2B.
  • additional element e.g., boundary element 110 and/or infill material 115
  • Sound dampening part 101 includes boundary element 110.
  • Boundary element 110 can be a rigid or semi-rigid element additively manufactured to include one or more internal structures 112 and a perimeter 114.
  • Boundary element 110 may be additively manufactured from a second coreactive composition, which may be based on a same or a different coreactive composition to each of structural element 105 and/or infill element 115.
  • boundary element 110 may comprise a polyurea-based coreactive composition.
  • the polyurea-based coreactive composition chemistry may be advantageous for the composition of boundary element 110 due to the sound/vibration dampening effect of polyurea-based coreactive compositions, as well as for the strength and rigidity that polyurea based compositions provide to physical structures (e.g., a relatively thin and strong material that can be printed in complex geometries).
  • boundary element 110 may be additively manufactured from any other coreactive composition described in Section II, as based upon a desired effect, and the selected coreactive composition may be adjusted with the inclusion of any one of the additives and/or fillers described in Section II to result in the desired effect.
  • covalent bonding forms between individual elements printed utilizing ARE type three-dimensional printing.
  • covalent bonds may form between boundary element 110 and infill material 115 filled into the voids of boundary layer 110, and may also form between the bottom surfaces of boundary element 110 and an upper surface of structural element 105 (if present).
  • Boundary element 110 may be additively manufactured to include each of perimeter 114 and structural elements 112. Specifically, perimeter 114 may form the outer walls/surfaces of boundary element 110, which provides the overall shape of boundary element 110.
  • perimeter 114 of boundary element 110 can be additively manufactured into any suitable shape, which can include irregular exterior boundaries, and/or non-planar surfaces.
  • Boundary element 110 may be additively manufactured to include one or more internal structures 112.
  • Internal structures 112 may be structures that are hollow, or otherwise comprise a void, which are arranged in any regular or irregular configuration about the interior of perimeter 114 of boundary element 110.
  • FIG.s 1A and IB depict internal structures 112 as comprising hollow hexagonal cells arranged in a lattice (e.g., repeat units of similar geometry). This orientation may be referred to as a honeycomb lattice-type structure and may be particularly suitable to accepting infill element 115, to be discussed further herein, while providing relatively high strength and rigidity to the overall structure of sound dampening part 101.
  • internal structures 112 may be selected based upon any suitable configuration.
  • internal structures 112 may comprise any combination of different uniform shapes (e.g., squares, circles, rectangles, pentagons, triangles, etc.) and/or irregular shapes/patterns (waves, lines, etc.) and can be arranged symmetrically (e.g., in a lattice-type configuration) or asymmetrically (e.g., randomly arranged) about boundary element 110, as based upon desired structural and/or sound absorbing effects.
  • Boundary element 110 may have a relatively low flexural modulus, as compared with other elements of sound dampening part 101, as measured by a flexural test such as ISO 178, such as between 108 MPa and 50 MPa.
  • the relatively low flexural modulus contributes to the relatively high rigidity and strength of boundary element 110, as has been described previously.
  • boundary element 110 also contributes to sound/vibration dampening, and also acts as a sound blocking portion of sound dampening part 101. Specifically, boundary element 110 may block sound in the 100 Hz and 9000 Hz (i.e., 9kHz) frequency range.
  • boundary element 110 can be adjusted, either alone or in combination, with the other elements of the acoustically dampening part 101 to achieve the desired sound dampening performance for a given application.
  • the size and shape of the internal structures 112 of boundary element 110 may be selected based upon a desired amount of infill material 115, as will be discussed in further detail herein.
  • the thickness of the walls of either the internal structures 112 or the outer perimeter 114 may be adjusted to result in a strong and rigid structure while minimizing weight.
  • the size of boundary element 110 may be adjusted in order for the overall thickness of the acoustically damping part 101 to comprise less than 5 inches in thickness, such as in the 0. 1 inch to 5 inch range, and more particularly in the 0.25 inch to 2 inch range, and still more particularly in the 0.25 inch to 1 inch range.
  • Sound dampening part 101 may include infill element 115.
  • Infill element 115 may act as a sound absorbing infill such as a colloidal or semi-colloidal mixture (e.g., a foam or foam-like material), that is additively manufactured or otherwise applied into the voids of the internal structures 112 of boundary element 110.
  • a colloidal or semi-colloidal mixture e.g., a foam or foam-like material
  • Infill element 115 may be additively manufactured, or otherwise formed from a third coreactive composition, which may be based on a same or a different coreactive composition to each of structural element 105 and/or boundary element 110.
  • infill element 115 may comprise a polyurethane-based coreactive composition.
  • the polyurethane-based coreactive composition chemistry may be advantageous to use as the composition of infill element 115 due to the sound absorbing effect of polyurea-based coreactive compositions.
  • polyurethane-based coreactive compositions may be advantageous in forming colloidal solutions/mixtures, whereas gasses (e.g., air, or other suitable gases) and/or additional materials can be suspended within the polyurethane-based coreactive composition forming a foam or foamlike material.
  • gasses e.g., air, or other suitable gases
  • infill element 115 may be additively manufactured from any other coreactive composition described in Section II, as based upon a desired effect.
  • the selected coreactive composition may be adjusted with the inclusion of any one of the additives and/or fillers described in Section II to result in a desired effect.
  • infill element 115 may include microcapsules, microspheres (e.g., such as ExpancelTM microspheres, commercially available from Nouryon), microballoons, and/or glass beads, that assist in creating a colloidal infill element 115.
  • the microspheres e.g., micro-balloon, microcapsule, etc.
  • the colloidal coreactive composition can have a targeted and/or desired density, as based upon the inclusion of the microspheres.
  • a base coreactive composition such as polyurea
  • sound dampening part 101 may be allowed to cure under ambient conditions for a given time.
  • sound dampening part 101 including infill material 115 containing the microspheres may be cured for a second time, and at a higher temperature range, in order to activate the expansion of the microspheres.
  • the second curing temperature may be between 80°C and 133°C.
  • the microspheres Once activated, the microspheres increase in diameter by as much as 400%, such as from about 10 pm to 40 pm, increasing the overall volume of the infill element 115 by up to approximately 6500%.
  • the volumetric expansion of the microspheres may be regarded as controllable, in that the expansion rate of the microspheres is temperature dependent and can be controlled as based upon the activation temperature and/or curing time.
  • the sound dampening part 101 including infill material 115 containing the microspheres may be allowed to post-cure for anywhere between approximately 2 hours and 15 hours, in order to allow for the expansion of the microspheres to a desired volume. Therefore, inclusion of the microspheres in infill material 115 can provide enhanced controllability over infill materials 115 not containing the microspheres.
  • covalent bonding forms between the individual elements of sound dampening part 101 printed utilizing ARE type three-dimensional printing.
  • covalent bonds may form between infill element 115 and each boundary element 110 (e.g., the walls of internal structures 112 and/or perimeter 114) and, if present, an upper surface of structural element 105.
  • boundary element 110 and infill element 115 may react and cure under ambient conditions to form a contiguous sound damping part 101.
  • internal structures 112 of boundary element 110 may be structures that are hollow, or otherwise comprise a void, which are arranged in any regular or irregular configuration about the interior of perimeter 114 of boundary element 110.
  • infill element 115 may be additively manufactured, or otherwise applied (e.g., by pouring and leveling, smearing in by hand, or spraying) into the voids of internal structures 112 of boundary element 110.
  • infill element 115 comprises a colloidal material, such material my flow and either partially or completely fill the voids of internal structures 112.
  • internal structures 112 are illustrated as comprising hollow hexagonal cells arranged in a lattice (e.g., a honeycomb lattice) and internal element 112 applied therein, as described previously, internal structures 112 may comprise any combination of different uniform shapes (e.g., squares, circles, rectangles, pentagons, triangles, etc.) and/or irregular shapes/patterns (waves, lines, etc.) and be arranged symmetrically (e.g., in a lattice-type configuration) or asymmetrically (e.g., randomly arranged) about boundary element 110.
  • infill element 115 may completely or partially fill the voids created by any of the foregoing configurations of internal structures 112.
  • the design, shape, and or organization of structural elements 112 may be based not only upon structural integrity /strength, but also an overall sound absorbing/deadening effect. Specifically, any of the shape, size, number, distribution, and/or organization of structural elements 112 may be based upon sound absorbing characteristics provided by infill materials 115.
  • infill element 115 may absorb sound (as compared to the sound deadening and blocking of each of structural element 105 and boundary element 110), in the 100 Hz and 9000 Hz (i.e., 9kHz) frequency range.
  • the amount of infill element 115 and/or the composition of infill element 115 may be selected based upon a desired sound absorbing characteristic, and any one of the characteristics of internal structures 112 may be selected based upon the desired amount or composition of infill element 115 to achieve the sound absorbing effect.
  • boundary element 110 may be adjusted in order for the overall thickness of the acoustically damping part 101 to comprise less than 5 inches in thickness, such as in the 0.1 inch to 5 inch range, and more particularly in the 0.25 inch to 2 inch range, and still more particularly in the 0.25 inch to 1 inch range.
  • the amount and/or composition of infill element 115 may also be adjusted to result in the same desired thickness.
  • FIGs. 2A and 2B illustrate sound dampening parts 201 and 202 that may be additively manufactured onto substrates 220A and 220B respectively.
  • Each of sound dampening part 201 may include structural element 205 A, which may be the same as structural element 105; boundary element 310 which may be the same as boundary element 110, and infill element 315A which may be the same as infill element 115.
  • sound dampening component 202 may comprise each of boundary element 21 OB which may be the same as boundary element 110 and/or infill element 215B which may be the same as infill element 115. Therefore, any of the foregoing embodiments discussed in relation to FIG.s 1A and/or IB may be incorporated into sound dampening parts 201 and/or 202.
  • each element of the sound dampening part 201 may be fabricated using ARE-type three-dimensional printing.
  • the sound dampening parts can be additively manufactured onto a substrate, such as substrates 220 A and 220B.
  • substrates 220 A and 220B For instance, structural element 205, boundary element 210, and/or infill element 215 may be additively manufactured directly onto a substrate 220 where substrate 220 comprises any suitable material such as metal, glass, wood, plastic, and the like.
  • structural element 205 A of sound dampening part 201 may be formed directly onto substrate 220A
  • boundary element 210B may be formed on structural element 205A thereafter
  • infill element 215B may be formed or otherwise applied into the voids of boundary element 210B.
  • boundary layer 210B and infill element 215B of sound dampening component 202 may be formed directly onto substrate 220B.
  • substrate 220 can be either a primary substrate or a secondary substrate.
  • a primary substrate may comprise a substrate where the sound dampening part is permanently affixed. This can include the interior walls of a vehicle, the walls of an architectural structure, the interior of a fuselage of an aircraft, the interior walls of a home appliance, and the like.
  • the primary substrate can be any one of, or combination of suitable materials such as metal, glass, wood, plastic, and the like.
  • a secondary substrate may comprise a substrate whereas the sound dampening part is temporarily affixed.
  • the secondary substrate may comprise a build material that is utilized during the additive manufacturing process, which is removed (e.g., either partially or completely) from the sound dampening part later. Thereafter, the sound dampening part may be applied to a primary substrate.
  • the boundary element 210B and infill element 215B may be formed onto substrate 220B where substrate 220B is a secondary substrate.
  • secondary substrate 220B can be removed (e.g., removing by force, by dissolving secondary substrate 220B, etc.), leaving only the sound dampening part 220B.
  • structural layer 205 A of sound dampening part 201 can be additively manufactured onto a secondary substrate, and a cured sound dampening part 201 can be removed and applied to a primary substrate thereafter.
  • the sound dampening parts can be described as being applied in place (e.g., printed onto a secondary substrate, which can be partially or completely removed, and applied to a primary substrate thereafter).
  • additive manufacturing of the sound dampening part can be accomplished via a three-dimensional printing system adapted for mixing and extruding feedstocks.
  • Such three-dimensional printing systems may utilize a gantry, or in other cases, may utilize a robotic arm adapted for three-dimensional printing.
  • a robotic arm equipped with a three-dimensional printing system may be used to additively manufacture sound dampening parts directly onto primary substrates, such as the hood of an automobile.
  • the robotic arm-equipped with a three-dimensional printing system can “print in place” the sound dampening part directly onto the desired primary surface.
  • a gantry-type printing system may be adapted for print-in-place applications of the sound dampening parts.
  • sound dampening component 360 may comprise each of: structural element 305B, which may be the same as structural element 105 A and/or structural element 205A; boundary element 310B which may be the same as boundary element 110A/B and/or boundary element 210A/B; and/or infill element 315B which may be the same as infill element 115A/B and/or infill element 215A/B.
  • Each of the sound dampening components 350 and 360 of multi-layer sound dampening part 301 may be formed to target a desired overall acoustical effect.
  • each of sound dampening components 350 and 360 may be additively manufactured to target 1 a desired frequency band/range of sound, which when combined into a multi-layer sound dampening part 301 blocks or otherwise reduces sound over a larger frequency band than a single layer sound dampening part.
  • first sound dampening component 350 and second sound dampening component 360 may be tuned, optimized, or otherwise adjusted, either alone or in combination, to target desired sound dampening characteristics (e.g., blocking/absorbing/reducing sound over different frequency bands/ranges), and once formed into the multi-layer sound dampening part, block or otherwise reduce sound over a larger frequency band that a single-layer sound dampening part.
  • desired sound dampening characteristics e.g., blocking/absorbing/reducing sound over different frequency bands/ranges
  • first sound dampening component 350 may be additively manufactured to block or otherwise reduce sound over frequency range X
  • second sound dampening component 360 may be additively manufactured to block or otherwise reduce sound over frequency range Y, where frequency range X may comprise at least a portion of sound waves from a different frequency than sound range Y.
  • multi-layer sound dampening part 301 may therefore block or otherwise reduce sound over a larger frequency range (e.g., X and Y), as compared to a single layer sound dampening component (e.g., X or Y).
  • ARE-type three- dimensional printing allows for covalent bonding to form between the individual layers of coreactive compositions, and therefore, covalent bonding can form between the individual sound dampening components (e.g., first sound dampening component 350 and second sound dampening component 360) to form a congruent multi-layer sound dampening part 301.
  • the individual sound dampening components e.g., first sound dampening component 350 and second sound dampening component 360
  • FIG. 3 is nonlimiting. For instance, more layers of sound dampening components may be present than those illustrated in FIG. 3.
  • Aspect 1 is an additively manufactured sound dampening part comprising a boundary element comprising a first coreactive composition; and an infill element comprising a second coreactive composition, wherein: the boundary element substantially encloses the infill element, and the sound dampening part provides a sound transmission loss of at least 30 dB(A) for a 125Hz to 8kHz sound passing through the sound dampening part.
  • Aspect 2 is the sound dampening part of aspect 1, wherein the first coreactive composition comprises a polyurea-based coreactive composition comprising: a first coreactive component including an isocyanate-containing compound, and a second coreactive component including an amine-containing compound.
  • Aspect 3 is the sound dampening part of either of aspects 1 or 2, wherein the second coreactive composition comprises a polyurea-based coreactive composition comprising: a first coreactive component including a hydroxyl-containing compound, and a second coreactive component including an isocyanate-containing compound.
  • Aspect 4 is the sound dampening part of any preceding aspect, wherein the boundary element further defines a perimeter of the sound dampening part.
  • Aspect 5 is the sound dampening part of any preceding aspect, wherein the boundary element comprises a plurality of internal structures, each internal structure comprising a void.
  • Aspect 6 is the sound dampening part of any preceding aspect, wherein the plurality of internal structures each comprise a hexagonal geometry arranged in a lattice.
  • Aspect 7 is the sound dampening part of any preceding aspect, wherein the infill element at least partially fills the void of at least one of the plurality of internal structures.
  • Aspect 8 is the sound dampening part of any one of any preceding aspect, wherein the infill element comprises a colloidal solution.
  • Aspect 9 is the sound dampening part of any one of any preceding aspect, wherein the infill element imparts a first sound dampening effect to the sound dampening part, and the boundary element imparts a second sound dampening effect to the sound dampening part different from the first sound dampening effect.
  • Aspect 10 is the sound dampening part of any one of any preceding aspect, further comprising a structural element comprising a third coreactive composition, wherein the structural element supports the boundary element and the infill element.
  • Aspect 11 is the sound dampening part of any preceding aspect, wherein the third coreactive composition comprises a Michael addition-based coreactive composition comprising:
  • Aspect 12 is the sound dampening part of either of any preceding aspect, wherein the structural element comprises a base structure of the sound dampening part, the structural element comprising a first surface upon which the boundary element and infill element are formed.
  • Aspect 13 is the sound dampening part of any one of any preceding aspect, wherein the infill element imparts a first sound dampening effect to the sound dampening part, the boundary element imparts a second sound dampening effect to the sound dampening part, and the structural element imparts a third sound dampening effect to the sound dampening part, each of the first sound dampening effect, the second sound dampening effect, and the third sound dampening effect comprising different sound dampening effects.
  • Aspect 14 is a method of additively manufacturing a sound dampening part comprising: depositing a boundary element in a first geometric configuration, the boundary element imparting a first sound dampening effect to the sound dampening part; and depositing an infill element in a second geometric configuration different from the first geometric configuration, the infill element imparting a second sound dampening effect to the sound dampening part different from the first sound dampening effect, and wherein the boundary element and the infill element react and cure under ambient conditions to form the sound dampening part.
  • Aspect 15 is the method of aspect 14, wherein the boundary element comprises a polyurea-based coreactive composition, and the first configuration comprises a plurality of internal structures each comprising a void.
  • Aspect 16 is the method of aspect 15, wherein each of the plurality of internal structures comprises a hexagonal geometry, and the internal structures are arranged in a lattice.
  • Aspect 17 is the method of either of aspects 15 or 16, wherein the infill element comprises a polyurethane-based coreactive composition, and the second configuration comprises an infill of the voids of the plurality of internal structures.
  • Aspect 18 is the method of any one of aspects 14 through 17, wherein the boundary element and the infill element are deposited onto a substrate.
  • Aspect 19 is the method of any one of aspects 14 through 17, further comprising depositing a structural element in a third geometric configuration, the structural element imparting a third sound dampening effect to the component different from the first sound dampening effect and the second sound dampening effect, the third geometric configuration being different from the first and the second configurations, and each of the boundary element, the infill element, and the structural element react and cure under ambient conditions to form the sound dampening part.
  • Aspect 20 is the method of any one of aspects 14 through 19, wherein the structural element comprises a polyurethane-based coreactive composition, and the third configuration comprises a base structure of the sound dampening part.
  • Aspect 21 is the method of any one of aspects 14 through 20, wherein the structural element is deposited onto a substrate, and the boundary element and the infill element are deposited onto the structural element thereafter.
  • Aspect 22 is a multi-layer sound dampening part comprising: a first sound dampening component comprising: a boundary element comprising a plurality of internal structures each comprising a void; an infill element configured within the voids of the plurality of internal structures; and optionally, a structural element upon which the boundary element and the infill element are formed, wherein the boundary element, the infill element, and the optional structural element react and cure under ambient conditions to form the first sound dampening component; and a second sound dampening component comprising: a boundary element comprising a plurality of internal structures each comprising a void; an infill element configured within the voids of the plurality of internal structures; and optionally, a structural element upon which the boundary element and the infill element are formed, wherein the boundary element, the infill element, and the optional structural element react and cure under ambient conditions to form the second sound dampening component, wherein the first sound dampening component comprises a first layer of the multi-layer sound dampening part and the second
  • Aspect 24 is a method for additively manufacturing any one of 1 through 13.
  • Aspect 25 is a system for additively manufacturing a component of any one of
  • Aspect 26 is a system of additively manufacturing a component according to any one of aspects 14 through 20.
  • a 3D printable 2K polyurea formulation with additives and rheology modifiers was printed and tested for noise reduction.
  • the amine and the isocyanate components were formulated using the compositions below.
  • the amine-side composition was made from the components in Table 3.
  • the isocyanate-side composition was made from the components listed in Table 4.
  • IPDI Isophorone diisocyanate
  • CAS# 98-4098-71-9 commercially available from Sigma Aldrich
  • the amine-side and isocyanate- side compositions were transferred from their respective DAC cups to 32oz cartridges via Flacktek SpeedDisc which is optimal for 3D printing by reactive extrusion via Viscotec 2K extruders mounted to a gantry such as the 3DP.
  • the amine and isocyanate compositions were printed at parameters listed in Table 5. Table 5
  • the formulation was printed with a 100% rectilinear infill pattern at a 45° angle to form a 13”xl3”x0.5” prism acoustic panel for noise reduction testing. Procedures for testing are documented in the test method section. The completed black flexible polyurea acoustic panel print was cured for 1 day at ambient conditions and 2 days at 140°F.
  • the acrylate side composition was made from the components in Table 8.
  • the amine-side and the acrylate-side compositions were transferred from their respective DAC cups to 32oz cartridges via Flacktek SpeedDisc which is optimal for 3D printing by reactive extrusion via Visoctec 2K extruder mounted to the gantry such as 3DP.
  • the amine and acrylate with epoxy compositions were printed at parameters listed in Table 9.
  • the white Aza-Michael formulation was printed with a 100% rectilinear infill pattern at a 45 0 angle to form a 13”xl3”x0.5” prism acoustic panel for noise reduction testing.
  • the completed white Aza-Michael acoustic panel print was cured for 1 day at ambient conditions and 2 days at 140°F. Procedures for testing are documented in the test method section, but a summary of relevant data is listed below in Table 10.
  • the white Aza-Michael formulation was completely printed first at a 100% rectilinear infill pattern at a 45 ° angle to form a 13”xl3”x0.12” prism directly on the printbed.
  • the black polyurea formulation was printed directly on top of the completed print of the white Aza-Michael material to form a 13”xl3”x0.35” prism.
  • the infill designs for the black polyurea portion of the acoustic panel are listed below in Table 11. The percentages for infill refer to the total panel area filled when looking down on the panel from a 2 dimensional plan view. Table 11
  • Example 4 Multi-Material Acoustic Panels containing Foam, Black Polyurea and White Aza-Michael
  • An acoustic testing apparatus was used to conduct sound dampening performance testing on the 3D ARE printed panels.
  • the apparatus consists of an aluminum rectangular enclosure with a noise source mounted at one end and a test panel mounted the other end.
  • the noise source is a tube featuring a loudspeaker at one end and an opening at the other end. The high noise generated through the loudspeaker radiates out of the open end of the tube and into the rectangular enclosure.
  • the other end of the rectangular enclosure is designed to accommodate mounting and dismounting of a square test sample and its acoustic insertion loss performance can be measured.
  • FIG. 4 shows the reduction in overall sound pressure levels passing through the center subarea (of approximately 10.5 inches by 10.5 inches) of the samples in Table 14 (summed up over all l/3rd octave bands between 125 Hz to 8 kHz).
  • the overall sound pressure level (approximately 111 dB A) was measured by the microphone installed inside the test enclosure.
  • the plot shows the overall sound pressure levels values in dBA units, which were measured outside the enclosure, for several different samples mounted in the apparatus. Specific samples designs are described elsewhere.
  • the highest insertion loss i.e., the most efficient noise isolation solution, is described by the samples that show the lowest sound pressure levels in dBA units.
  • the sample labeled “Black flexible” shows the highest insertion loss which may be attributed to its favorable combination of structural and sound dampening materials.
  • FIG. 5 shows the reduction in overall sound pressure levels for the samples described in Table 15. The highest insertion loss is demonstrated by the “Lead (Pb)” sample.
  • FIG. 6 shows the sound transmission loss (dB) vs. frequency for the center area of the panels in Table 14.
  • Example 6 Expandable ARE Foam for Acoustic Dampening
  • a 3D printable 2K polyurea formulation with expandable fillers, additives, and rheology modifiers was printed for noise reduction.
  • the amine and the isocyanate components were formulated using the compositions below.
  • the amine-side composition was made from the components in Table 17.
  • the isocyanate-side composition was made from the components listed in Table 18.
  • IPDI Isophorone diisocyanatc IPDI, aliphatic diisocyanatc, CAS# 98-4098-71-9, commercially available from Sigma Aldrich
  • the completed expandable foam polyurea panel print was cured for 2 days at 160°F. Once cured the polyurea material was placed in an oven at 125°C for 40 minutes to activate the expandable filler. The polyurea sample expanded with an increase in volume up to 850 %.
  • the expandable polyurea foam was used to create an acoustic dampening panel both on its own and in place of the foam in Example 4. In both configurations, the expandable polyurea contributed significantly to the acoustic dampening effect of the material, especially in the high frequency region.

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Abstract

L'invention concerne une pièce d'atténuation phonique fabriquée de manière additive (102) comprenant un élément de délimitation (HOB) comprenant une première composition coréactive ; et un élément de remplissage (115B) comprenant une seconde composition coréactive, l'élément de délimitation entourant sensiblement l'élément de remplissage, et la pièce d'atténuation phonique fournissant une perte de transmission sonore d'au moins 30 dB (A) pour un son de 125 Hz à 8 kHz traversant la pièce d'atténuation phonique.
PCT/US2024/060070 2024-02-14 2024-12-13 Matériaux d'atténuation phonique imprimés en 3d Pending WO2025174452A1 (fr)

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WO2022005596A1 (fr) * 2020-07-02 2022-01-06 Ppg Industries Ohio, Inc. Système pour la production rapide d'objets à l'aide d'une conception de remplissage par écoulement
CN115620692A (zh) * 2022-09-28 2023-01-17 西安交通大学 一种变刚度吸声超材料及其制备方法

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US20220064481A1 (en) * 2017-06-27 2022-03-03 Lawrence Livermore National Security, Llc Microballoon-facilitated tunable porosity of elastomeric shape memory polymer composites
EP3768494B1 (fr) * 2018-08-01 2023-04-19 Carbon, Inc. Production de produits de faible densité par fabrication additive
WO2023037263A1 (fr) * 2021-09-13 2023-03-16 Intrepid Automation Mousses expansives en fabrication additive

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Publication number Priority date Publication date Assignee Title
WO2022005596A1 (fr) * 2020-07-02 2022-01-06 Ppg Industries Ohio, Inc. Système pour la production rapide d'objets à l'aide d'une conception de remplissage par écoulement
CN115620692A (zh) * 2022-09-28 2023-01-17 西安交通大学 一种变刚度吸声超材料及其制备方法

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