The described embodiments relate generally to a micro-perforated panel systems and methods for noise abatement and method of making a micro-perforated panel system. In particular, embodiments relate to glass micro-perforated panel systems and methods for their construction.

An acoustic-absorber system incorporates a plurality of acoustic-baffle assemblies in cooperation with an acoustic cavity. Each acoustic-baffle assembly incorporates a plurality of nested fluted cups, wherein at least one fluted cup of a first type having at least one orifice at at least one radially-inwardly-extending grooved portion is interleaved with at least one fluted cup of a second type having at least one orifice at at least one radially-outwardly-extending ridged portion. Externally-generated soundwaves entering either from the inside of an innermost fluted cup, or from the outside of an outermost fluted cup, travel through the at least one orifice thereof, and along a circuitous path along the gaps between adjacent cups and through at least one orifice of each of other fluted cups from one gap to another, until finally propagating into the acoustic cavity through at least one orifice of the outermost, or innermost, fluted cup for subsequent additional attenuation by destructive interference from phase cancellation within the cavity.

An assembly forming an acoustic insulator having a first sheet, a pierced second sheet, and a plurality of first and second structures. Each first structure comprises a first and a second strip, wherein each is shaped to form half of the wall of a cage and wherein, for two successive halves, each strip comprises a facet of a joining wall. Each second structure is made up of a first and a second strip, wherein each is shaped to form half of the wall of a cone, wherein. For each strip, at least one of the wall halves of each cone is pierced. For two successive halves, each strip comprises one facet of the connecting wall. Each cone is located in a cell and each connecting wall is located between the two facets of a joining wall, and, between two adjacent first structures, a second structure is likewise fitted.

An acoustical panel apparatus includes a laminate panel substrate that is receptive to ink printing operations. The substrate may be provided with folding grooves to form an apertured base, a sidewall, and an inner wall which together define a receptacle. An acoustical tuning body is positionable at the receptacle to attenuate at least one of sound transmissions and sound reflections from sound passing through the apertures in the base. A mounting bracket is attached to the panel to secure the acoustical tuning body at the receptacle and for mounting the panel substrate to a wall or ceiling.

An exemplary inventive acoustic wall panel includes a pair of congruent flat rectangular plates and a housing. The two plates adjoin at their respective vertical edges to form an angle between the two plates, wherein 90<180. Each plate has a material characteristic relating to acoustic reduction through the plate. Design of an inventive wall panel includes selection of the angle and the respective plate materials, with an objective of producing counteractive acoustic vibratory motions in the two plates in response to sound waves impinging upon the inventive wall panel. Acoustic vibratory motion is induced in each plate whereby the respective vibratory motions tend to oppose each other, thereby reducing sound transmission across the inventive wall panel. The housing lends support to the two attached plates and facilitates connection of the inventive wall panel to another inventive wall panel or to a different structure.

In a sound-absorbing device (1) which is suspended from ceilings (3) in rooms (2), comprising a frame (4) which is fastened at a distance from the ceiling (3) and parallel thereto, and at least one flat structure with sound-absorbing properties which is inlaid or inserted into the frame (4),
on the one hand a sound-absorbing property should be present as far as possible over the entire surface of the ceiling (3) and on the other hand sufficient illumination should be possible for the interior of the room. This is solved in accordance with the present invention by at least one intermediate space (11) being provided in the flat structure (5), by one or more lighting means (12) being arranged in the respective intermediate space (11), and by each of the lighting means (12) being locked to the frame (4) directly or by means of support elements (13).

A housing for an aero-acoustic processing machine having rotational drive apparatus coupled to rotate an air impeller to draw air and material to be processed through an axial inlet system and expel the air and processed material through a transverse outlet. The housing includes an enclosure incorporating at least one layer of noise attenuation materials surrounding the aero-acoustic processing machine, the enclosure having a material inlet port, an air inlet port and an exhaust port for outputting processed product with air. Airflow paths that are required for operation of the aero-acoustic processing machine are provided to enable airflow into the housing whilst significantly reducing noise emission.

There is provided a soundproof structure that can selectively block sound having a specific frequency emitted from equipment, automobiles, and general households and can change the cutoff frequency of the sound in accordance with a change in the frequency of sound to be blocked. The above problem is solved by providing a laminated film, in which two or more films each including one or more holes drilled therein are laminated, and two rigid frames, which fix the laminated film so as to be interposed from both sides of the laminated film, and making at least parts of the one or more holes in the respective films of the laminated film overlap each other.

An object is to provide a soundproofing structure which exhibits high soundproofing performance in a broad frequency band, can be miniaturized, can ensure ventilation properties, and has a light transmittance, and a cylindrical structure, a window member, and a partition member including this soundproofing structure. Provided is a soundproofing structure including: a soundproofing cell which includes a frame having a frame hole portion passing therethrough and a film that covers the frame hole portion and is fixed to the frame, in which the film has a plurality of through-holes passing therethrough in a thickness direction, an average opening diameter of the through-holes is in a range of 0.1 m to 250 m, and a vertical direction of a film surface is disposed so as to be inclined with respect to a direction of a sound source to be soundproofed.

Provided is a soundproofing structure including: a plate-like member which has a plurality of through-holes passing therethrough in a thickness direction, in which in a case where an average opening diameter of the through-holes is 0.1 m or greater and less than 100 m, and in a case where the average opening diameter of the through-holes is set as phi (m) and a thickness of the plate-like member is set as t (m), an average opening ratio rho of the through-holes is greater than 0 and less than 1 and falls in a range where a center is rho_center=(2+0.25t)phi.sup.1.6, a lower limit is rho_center(0.052(phi/30).sup.2), and an upper limit is rho_center+(0.795(phi/30).sup.2).