To manufacture a motor vehicle composite component, plastic particles are introduced into a mold cavity of a mold and are connected there to one another to form a particle foam. The mold is then adjusted while the mold cavity changes, and a thermoplastic plastic is then injected into the mold cavity while a carrying element and/or at least one fastening element are formed, wherein the thermoplastic plastic is bonded to the particle foam at least by connection in substance. The aforementioned materials may also be introduced in the reverse order. The mold is then adjusted once again while the mold cavity changes, and a metal melt is then injected into the mold cavity, as a result of which an electrical strip conductor and/or at least one metallic fastening element are formed.

A manufacturing method for a child carrying device includes the following steps: providing a mold and disposing a main body of the child carrying device into the mold, and injecting a foam material into a cavity of the mold and foaming the foam material so as to form a flexible layer integrated with the main body. The manufacturing method disposes the main body into the mold and directly forms a flexible layer on the main body, so that the flexible layer ensures safety and comfort of the child carrying device while saves the necessity to dispose a seat pad or a cushion and fixing structures on the main body, and thereby reduces the cost and the work-hour of assembly, and the overall weight of the child carrying device can be reduced by omitting the fixing structures.

A method for the production of a vehicle body element is disclosed, wherein the vehicle body element is provided as a component composite comprised of at least one carrier profile part having a hollow structure, and a lightweight material, for example plastic. A liquid starting component of the lightweight construction material is introduced into the hollow structure of the carrier profile part and is then cured to forms the component composite.

A tool for the production of particle foam parts through the welding of foam particles by means of electromagnetic waves comprises two mould halves which bound a mould cavity. At least one of the two mould halves is made of a material which is transparent to electromagnetic waves and has a boundary wall which bounds the mould cavity and one or more supports serving to support the boundary wall on a capacitor plate on the side facing away from the mould cavity and forming one or more hollow spaces. A tool system for the production of particle foam parts has the tool and at least one trimming body, which is designed for introduction into the hollow space or at least one of the hollow spaces. A method for the production of a particle foam part with the tool or tool system is also specified.

An intra-mode moulding foam molding device of thermoplastic polymer particles and a molding method thereof. The device includes a supercritical fluid delivery system, a mould pressing foaming system, a preheating quantitative feeding system and a moving rail; the supercritical fluid delivery system communicates with the mould pressing foaming system. Through a one-step foam molding method of polymer particles, polymer particles can be directly added into a molding cavity without pre-foaming, water and anti-sticking separating agent are not needed; the molding process does not need high-pressure water vapor for warming and molding, and has great adhesion force and is also clean, therefore polymer materials are easy to hydrolyze. The processing needs few heat, the heating efficiency of the polymer particles is high, the temperature of the polymer particle is uniform, and a polymer particle microcellular foamed mould pressing molded product having fine pores, precise size and light weight is obtained.

An intra-mode moulding foam molding device of thermoplastic polymer particles and a molding method thereof. The device includes a supercritical fluid delivery system, a mould pressing foaming system, a preheating quantitative feeding system and a moving rail; the supercritical fluid delivery system communicates with the mould pressing foaming system. Through a one-step foam molding method of polymer particles, polymer particles can be directly added into a molding cavity without pre-foaming, water and anti-sticking separating agent are not needed; the molding process does not need high-pressure water vapor for warming and molding, and has great adhesion force and is also clean, therefore polymer materials are easy to hydrolyze. The processing needs few heat, the heating efficiency of the polymer particles is high, the temperature of the polymer particle is uniform, and a polymer particle microcellular foamed mould pressing molded product having fine pores, precise size and light weight is obtained.

Low-density thermoplastic expandable microspheres are disclosed. Various low-density structures, in particular, sandwich panels, based on foam prepared from the low-density microspheres, are also disclosed. Process of preparing low-density polymeric microspheres, per se, and the corresponding low-density structures, based on the microsphere foam, are also disclosed.

High-temperature foams are produced and used in the construction of aeroplanes, ships and rail and other vehicles. In particular, the foams are further processed into sandwich materials by joining with two outer layers. To this end, a novel process is used for producing high-temperature foams (HT foams) which are particularly suitable for producing such sandwich components for lightweight construction. This process achieves an improvement in the processability of the HT foams produced and a weight reduction of the sandwich materials. The HT foams are furthermore rigid particle foams which are markedly more economic to produce than rigid block foams. In particular, a reduction is brought about in resin absorption in fibre composite processes through a process-related optimization of the surface constitution.

The invention relates inter alia to a method of making a thin component (10) in lightweight sandwich construction with a high-quality surface (26).

A thermal insulation injection gun includes a pointed nozzle that prevents blocking of the nozzle by a distal panel of a building cavity and/or by pre-existing insulation within the cavity. In embodiments, the pointed nozzle can be pressed through a panel, thereby forming the injection hole. An enhancement port can be provided through which an enhancing material such as a carrier fluid, particulate or fibrous insulating material, a binder, or a fire retardant can be added and mixed with the insulating material. Embodiments include expanding nozzle wings that can compress pre-existing insulation to create a space on a proximal or distal side thereof for injecting the insulation. A compressible sheath installed over the nozzle can prevent dripping of excess insulation from the panel hole. Exchangeable collars can be used to fix an insertion depth of the nozzle and/or to block selected lateral dispensing ports of the nozzle.