Briefly, a variety of embodiments of composite materials including part fabrication using composite materials is described.

Briefly, a variety of embodiments of composite materials including part fabrication using composite materials is described.

A system (400) for cutting and conveying cushioning material includes an infeed conveyor system (402), a cutting mechanism (404), and a discharge conveyor system (406). The infeed conveyor system conveys a supply of cushioning material. The cutting mechanism cuts pieces of the cushioning material from the supply of cushioning material conveyed by the infeed conveyor system. The discharge conveyor system captures and discharges the pieces of the cushioning material. The discharge conveyor system includes a first conveyor (428) in a fixed planar position and a second conveyor (430) that rotates about an upstream roller (440) of the second conveyor. A downstream roller (442) of the second conveyor is biased toward first conveyor. A driving mechanism rotates at least one conveyor belt (438) on one or more of the first conveyor or the second conveyor.

The present invention relates to a method for cutting rigid foams, especially slabstock P(M)I foams. A method is provided here, by means of which it is possible to cut these rigid foams even in relatively high layer thicknesses of, for example, more than 3 mm, without material loss, which is produced in relevant amounts, for example, in the course of sawing as a result of the sawdust formed.

Thermally laminated foam boards, methods for making thermally laminated foam boards, apparatus for making thermally laminated foam boards, smaller foam pieces made from thermally laminated foam boards, methods for making smaller foam pieces from thermally laminated foam boards, parts made from thermally laminated foam boards, methods for making parts from thermally laminated foam boards, and tools for making parts from thermally laminated foam boards are disclosed. The thermally laminated foam boards are made by thermally bonding at least two polystyrene boards together.

An assembly for cutting a polystyrene block includes a lever element, adapted to be coupled to a hot cutting element, and a control device connected thereto. The lever is arranged so that a potential inclination of the hot cutting element can be followed during the feed motion of the cut, the lever further cooperating with a sensor set to detect a potential inclination deviation of the lever during the cut, in relation to an initial reference inclination, the control device being set to vary feed motion speed depending on the detected variation of inclination.

Device for cutting double curvature surfaces into expanded polystyrene foam volumes comprising a first pair of linear guides; over each of the linear guides two pairs of plates arranged over skids are moving, where a horizontal beam connects each pair of plates; the two pairs of plates and the pair of horizontal beams; a block of material supported on the plates is displaced by a first pair by of step motors simultaneously activated; where the block of material in its movement faces a rectangular frame which is arranged perpendicularly to the movement path of the block, with the rectangular frame having a fixed position and a flexible foil, which is covered with a sheath of thermal and electrical insulation, over which a resistive heating wire is helically wound where electrical current heats the wire and vaporizes the zone previous to physical contact with the block of material during displacement.

Particular embodiments of the inventive technology relate to apparatus and methods for cutting multi-layered material to reconfigure it so it may be used to construct sub-compartments in a larger storage container. The inventive technology, in particular embodiments may feature one or more of the following: dual blades, staggered blades (where one blade is more forward than another), a blade(s) angled upwards and forwards, blades separated in a left-right direction, prong recesses to accept trailing tips of blades, a rearwardly angled handle and/or a removed material ejection ramp, in conjunction perhaps with other features such as, e.g., a guide prong. One or more of such features may appear in the various manifestations of a defluting cutter or through cutting apparatus, whether guided or unguided, and/or manual or powered.

The invention relates to a method for producing a film (2) or sheet from a block material, in particular from a slabstock foam (3), in which at least the following regions are provided, as seen in a production direction (P) of the film (2) or sheet: a cutting region (I) for cutting the film (2) or sheet, wherein the film (2) or sheet is cut out, in a slitting-open manner, by means of a cutting unit (10) from the block material, which is continuously fed to the cutting region (1); also a passing-on region (II), adjoining the cutting region (I) and having a driven passing-on roller (20) for conveying the film (2) or sheet out of the cutting region (I); and also a secondary region (III), adjoining the passing-on region (II) and intended for further processing the film (2) or sheet, in particular a winding region (III) for winding the film (2) or sheet into a coil (4). In this case, there is a cutting-region stress in the film (2) or sheet in the cutting region (1) upstream of the passing-on roller (20), and there is a secondary stress in the film (2) or sheet in the passing-on region (II) upstream of the secondary region (III), in particular winding region (III). The invention also relates to an installation (1) for film or sheet production, and to a method for retrofitting an installation (1) for film or sheet production, and to a system for retrofitting an installation for film or sheet production.

A method for separating a dry fiber composite fabric, to a use of a separating device for separating a dry fiber composite fabric and to a wind power installation. A method for separating a dry fiber composite fabric with a multiplicity of fabric layers arranged one on top of the other, comprising providing the dry fiber composite fabric and a separating device, separating the dry fiber composite fabric with the separating device, which comprises a separating element with a toothing, wherein the toothing has a wave profile with a plurality of teeth, wherein the separating is performed by a substantially translational movement of the toothing on and/or in the dry fiber composite fabric with a stroke that is greater than a tooth tip spacing of two adjacent teeth of the toothing.