A honeycomb structure comprising carbon-fiber non-woven, sandwich structure comprising the honeycomb structure, and process for the production of the honeycomb structure.

A pipe-liner system for lining a pipe and methods of use thereof. A continuous, eversible extended liner is formed from a pipe-liner attached to an extender-tube via a substantially leak-proof connection there between. Lengths of the extender-tube and the pipe-liner are each chosen so that the pipe-liner is caused to be accurately positioned within the pipe upon everting the extended liner into the pipe by a pressurized fluid. The pipe-liner is held against an interior surface of the pipe being lined by inserting an inflatable bladder into the extended liner and filling the bladder with pressurized fluid. When a resin in the pipe-liner has hardened, the bladder is removed and the extender-tube is detached from the pipe-liner.

FIG. 2 shows a microperforated panel absorber 22 comprising: a microperforated facing 24; a non-perforated facing 26; and a cellular core structure 28 therebetween; the core structure 28 provides a number of primary cells 33 and a number of secondary cells 37; the secondary cells 37 each provide a reduced cell depth in comparison to the primary cells 33. FIG. 9 shows that the number of the primary cells 33 and the number of the secondary cells 37 ensures that sound absorption at frequencies up to and including the peak frequency is substantially maintained and that the sound absorption at frequencies higher than peak frequency is substantially increased relative to a comparable panel absorber in which the secondary cells are effectively replaced by primary cells.

A method of forming a thermoplastic cellular structure includes positioning a lower surface of a trough of a first corrugated thermoplastic sheet against an upper surface of a crest of a second corrugated thermoplastic sheet; positioning a support against a lower surface of the crest of the second corrugated thermoplastic sheet; and pressing a thermoplastic welding element against an upper surface of the trough of the first corrugated thermoplastic sheet so that at least a portion of the lower surface of the trough of the first corrugated thermoplastic sheet melts and bonds to at least a portion of the upper surface of the crest of the second corrugated thermoplastic sheet.

Core element for sandwich elements, wherein the core element has at least two hemisphere panels which are combined with one another, wherein each hemisphere panel has, between planar portions, and spaced apart from one another, uniform hemispherical elevations, wherein the two or in each case two hemisphere panels face one another by way of their elevations, wherein, with two or in each case two hemisphere panels combined with one another, the elevations of one hemisphere panel each bear with their apexes or apex surfaces against a planar portion of the other hemisphere panel, and wherein two hemisphere panels are connected to one another by virtue of the elevations being connected, in the region of their apexes or apex surfaces, to the planar portion of the other or another hemisphere panel against which they bear. Moreover, the invention also relates to the use of a core element and to a method for producing a core element.

Core element for sandwich elements, wherein the core element has at least two hemisphere panels which are combined with one another, wherein each hemisphere panel has, between planar portions, and spaced apart from one another, uniform hemispherical elevations, wherein the two or in each case two hemisphere panels face one another by way of their elevations, wherein, with two or in each case two hemisphere panels combined with one another, the elevations of one hemisphere panel each bear with their apexes or apex surfaces against a planar portion of the other hemisphere panel, and wherein two hemisphere panels are connected to one another by virtue of the elevations being connected, in the region of their apexes or apex surfaces, to the planar portion of the other or another hemisphere panel against which they bear. Moreover, the invention also relates to the use of a core element and to a method for producing a core element.

A protective case for an electronic device includes an elastomeric cover having a single piece of elastomeric material that conforms to the electronic device when the electronic device is installed in the protective case. The cover includes a button actuator to transfer a force applied on an outside surface of the elastomeric cover to a control button of the electronic device inside the elastomeric cover and a front opening in the elastomeric cover that provides access to a touch screen interface of a front of the electronic device. The cover also includes a plurality of recesses formed in at least one interior side surface of the elastomeric cover. The plurality of recesses soften the elastomeric cover in the selected area by reducing an average density of the elastomeric cover in the selected area of the elastomeric cover.

A composite wall assembly edge joint including a first composite buildup pad having a first tapered section is secured to and extends along a first composite face sheet. A second composite buildup pad having a second tapered section is secured to and extends along a second composite face sheet, wherein the first and second composite buildup pads are positioned between spaced apart first and second composite face sheets. A composite flute core member includes a tapered first portion positioned between and secured to the first tapered section and to the second tapered section. A second portion of the composite flute core member extends in a direction away from the tapered first portion of the composite flute core member and is positioned between, extends along and is secured to the first and second composite face sheets.

The invention describes a device and method for making corrugated products. The device can be used with any substrate and includes, at least, first and second drive rollers for driving a middle substrate and a single wall corrugated product. In other embodiments the invention includes upper drive rollers, lower drive rollers and middle drive rollers for driving an upper substrate, a lower substrate and a middle substrate. The middle substrate is driven between the upper and lower substrates at a higher velocity to form flutes that are anchored between the upper an lower substrates thereby forming a corrugated product. The invention also provides for customized corrugated products having multiple fluted substrates in various desirable arrangements. Examples of such products include mattress, partition panels, other furniture and construction products.

A method for producing a panel includes steps of providing a core element, covering the core element with a strip of impregnable flexible material that continues beyond the core element, providing a following core element alongside the preceding covered core element on that portion of the strip of flexible material that extends beyond the preceding core element, covering the following core element with a following strip of flexible material that extends beyond the following core element, and repeating each of those steps at least once. The method further includes impregnating the strips of material with a hardenable fluid, and hardening the impregnated strips. Each following strip of flexible material is fitted over the top face of a following core element, as well as over the preceding strip of flexible material extending over the top face of a preceding core element.