A module ensuring an acoustic attenuation of a flow of a first fluid and a heat exchange between the first fluid and a second fluid. The module comprises a perforated first wall with a cutout, a second wall, a cellular structure extending from the second wall to the first wall, a recess provided in the cellular structure between a perforated bottom and a perforated top, and a heat exchanger which is fixed inside the recess between the bottom and the top and in which the second fluid circulates. Such a module ensures an attenuation of sound waves and a heat exchange without limiting the attenuation surface.

The present teachings generally relate to an acoustic panel including a backing layer, honeycomb core attached to the backing layer, a mesh layer attached to the honeycomb core, and a face sheet including a flexible acoustic fabric face sheet attached to the mesh layer. The acoustic fabric face sheet can provide improved sound dampening characteristics over, for example, a perforated face sheet, and at a lower manufacturing cost, weight, and a simplified manufacturing process. The acoustic fabric face sheet can be or include a flexible woven and/or knitted fabric including a polymer such as an aromatic polyamide that includes a meta-aramid fiber, or a fiberglass fabric.

The present invention provides a sound attenuating apparatus including a substrate element comprising at least one first heterogeneous material, and at least one region comprising at least one further heterogeneous material at least partially located in the substrate element, wherein the at least one further heterogeneous material has at least one more scale of heterogeneity than the at least one first heterogeneous material. The present invention provides a method and apparatus for attenuating sound through a cavity construction in buildings and vehicles or the like, wherein the method comprises locating at least one region of adsorptive material in a cavity defined between a first wall region and a further wall region to attenuate sound transmission across the wall regions.

In an insulating element (1) for bounding spaces to be thermally insulated, e.g. for transport or packaging containers, comprising an in particular plate-shaped substrate element (2) made of a material having a low thermal conductivity, such as a polymer, the substrate element (2) is provided with a metallic coating (3) having a low emissivity in order to reduce the thermal radiation, yet is applied in a layer thickness of <80 nm, preferably <50 nm, such that the thermal conduction of the metallic coating will only insignificantly reduce the thus optimized insulating value. The metallic coating in the nanometer range does not only reduce the thermal radiation, but also enables optimal gas tightness with minimal thermal conduction.

Disclosed is a thermal insulation panel, in particular for thermally insulating edifices, said thermal insulation panel containing at least one aerogel and being open to diffusion along the main insulating direction of the panel.

An insulation product made from a panel having honeycomb-shaped cells filled with aerogel material. The aerogel material may be either a powder that is deposited into the cells after the aerogel has been formed or the aerogel may be formed in situ within the cells by a sol-gel process that optionally uses TEOS as a reaction precursor followed by ambient drying.

The present application discloses a thermally insulating aerogel vacuum composite panel and a preparation method thereof. The preparation method includes the following steps: (1) mixing TEOS solution and a metal particle, adding a hydrophobic agent, mixing, adding ammonium trifluoroacetate solution dropwise until completely gelating to obtain a metal aerogel precursor; (2) adding the metal aerogel precursor into an acid replacement solution for replacement for 1-24 h to obtain a gel; (3) washing the gel with deionized water to obtain a neutral gel; (4) soaking the neutral gel obtained in step (3) in a first organic resin solvent; (5) pouring the neutral gel into a substrate with honeycomb structure, and aging for re-gelating to obtain a modified panel; (6) drying the modified panel to obtain a honeycomb panel; and (7) aging the honeycomb panel at room temperature for 1-24 h to obtain the vacuum composite panel.