A laser weldable composition comprising a polyester component, 5 to 50 weight percent of a filler; and 10 to 30 wt. % of a poly(ester-carbonate) copolymer comprising carbonate units and ester units of the formula (I) wherein: T is a C.sub.2-20 alkylene, a C.sub.6-20 cycloalkylene, or a C.sub.6-20 arylene; R.sup.1 and J are each independently (a) a bisphenol A divalent group, and (b) a C.sub.16 or higher divalent group (b1), (b2), or (b1) and (b2), wherein (b1) is a phthalimidine divalent group, and (b2) is a third divalent group, wherein the C.sub.16 or higher divalent group (b1), (b2) or a combination of (b1) and (b2) is present in an amount of 40 mol % to 50 mol % based on the total moles of the bisphenol A divalent groups and the C.sub.16 or higher divalent group; and the composition, when molded into an article having a 2.0 mm thickness, provides a near infrared transmission at 960 nanometers of greater than 50% and a thermal resistance according to HDT 1.8 MPa flat (ISO 75/Af) is greater than 160 C. ##STR00001##

The present invention provides a method for producing a joined body, the method including: disposing a joining member between a member A containing a thermoplastic resin and a member B containing a thermoplastic resin, the joining member including a sheet part containing a thermoplastic resin, and a plurality of protrusion parts integrally formed with the sheet part on at least one surface of the sheet part, the protrusion parts containing a thermoplastic resin; and melting at least a part of the joining member to join the member A and the member B to obtain a joined body thereof.

A number of variations may include a product that may include a final part that may include a first part that may include a first face and may define at least one through hole and a second part that may include a second face, at least one stake, and at least one energy director that may be disposed between the first face and the second face wherein the first face and the second face may be abutted against one another and the at least one stake may be passed through the at least one through-hole and the first part and the second part have been ultrasonically staked and ultrasonically welded such that an ultrasonically welded interface may be formed between the first part and the second part.

The invention pertains to a composite part with a fibrous reinforcement and a thermoplastic polymer matrix, comprising: substrate part with a matrix of a first thermoplastic polymer having a first melting temperature; stiffener made of a composite material with a matrix of a second thermoplastic polymer having a second melting temperature; comprising the steps of: obtaining an unconsolidated preform of the substrate part; obtaining a preform of the stiffener; integrating a layer of the first thermoplastic polymer into the preform of the stiffener at a location configured to be in contact with the substrate part; and subjecting the substrate part and the preform of stiffener to a thermomechanical cycle so as to consolidate the substrate part and weld the stiffener to the substrate part.

One example method for producing a component from organic sheets may comprise placing a first organic sheet and a second organic sheet next to one another to form a component preform, forming at least one overlapping joining zone by tacking the first and second organic sheets together with a connecting part in the form of a third organic sheet, transferring the component preform to a joining tool, using the joining tool to form a joined component by connecting the organic sheets through melting and compression in the overlapping joining zone, and consolidating the joined component at least in the zone of the overlapping joining zone.

A fiber composite component assembly (100) includes a fiber composite component (3) including a base material and a fiber material, and a tolerance compensation layer (5) for joining the fiber composite component (3) to a further component (1), the tolerance compensation layer (5) including a fiber composite portion (17) and/or a further layer portion (7). A fiber composite component system (200) including a fiber composite component assembly (100) and a further component (1) joined to the fiber composite component assembly (100), as well as a method for producing a fiber composite component system (200), is also provided.

Disclosed are thermoset/thermoplastic composites that include a thermoset component directly or indirectly bonded to a thermoplastic component via a crosslinked binding layer between the two. The crosslinked binding layer is bonded to the thermoplastic component via epoxy linkages and is either directly or indirectly bonded to the thermoset component via epoxy linkages. The composite can be a laminate and can provide a route for addition of a thermoplastic implant to a thermoset structure.

A method for producing a composite component, which has a first section and a second section connected to the first section, the first section including a metallic material, the second section including a plastic, the first section having a first base region and projections provided on the first base region, and the projections provided on the first base region being anchored in the second section in order to bring about the connection between the first section and the second section, includes: manufacturing the first base region of the first section; creating the projections directly on the first base region by way of an additive manufacturing method; and connecting the second section to the first section.

A manufacturing method for a joined body, includes: bringing a first member and a second member into contact with each other, at least one of the first member and the second member being made of thermoplastic resin, and the second member having a recessed portion on a joining surface to be joined to the first member; and welding the first member and the second member together, including welding a contact portion of the first member and the second member by melting the thermoplastic resin by frictional heat generated in the contact portion by relative movement of the first member and the second member, in a state in which the first member and the second member are in contact with each other.

A manufacturing method of a thermoplastic continuous-discontinuous fiber composite sheet is provided, including providing a thermoplastic composite including a continuous fiber and a first thermoplastic resin. A mechanical treatment is performed on the thermoplastic composite to form a plurality of fragments such that the continuous fiber is changed into a discontinuous fiber. At least one thermoplastic discontinuous fiber aggregate layer is formed using the plurality of fragments as a raw material. The at least one thermoplastic discontinuous fiber aggregate layer is thermally compressed with at least one thermoplastic continuous fiber layer.