Provided is a thermoplastic resin composition, including (a) 100 parts by weight of a thermoplastic resin including 80-100% by weight of a base resin and 0-20% by weight of a reinforcing resin; (b) 2-60 parts by weight of linear carbon fibers having an average diameter of 1-15 μm; (c) 1-5 parts by weight of carbon nanofibrils having a BET specific surface area of 200-400 m.sup.2/g; (d) 1-15 parts by weight of carbon nanoplates; and (e) 1-25 parts by weight of metal powder, a method of preparing the thermoplastic resin composition, and an injection-molded article manufactured using the thermoplastic resin composition. The thermoplastic resin composition has excellent mechanical properties, e.g., impact strength, and also excellent conductivity, heat resistance, and electromagnetic wave shielding capacity, particularly high shielding efficiency against high-frequency electromagnetic waves, and thus can be used as automobile, electric, and electronic parts, and as a substitute for aluminum alloys and magnesium alloys.

A method for making radiation shielding or a hollow coupon that can be filled with a material that blocks or absorbs radiation. The invention also encompasses radiation shielding made by this method and a method of using radiation shielding during clinical irradiation procedure.

A flowable liquid formulation for 3D printing is described. The formulation comprises from 0.1 to 25 wt. % radiopaque particles, wherein at least 50% by weight of the particles have a diameter of at most 100 nm. The formulation further comprises monomeric, oligomeric and/or polymeric precursors adapted for polymerization to form a solidified article. Also described is an article (100) formed by 3D printing, the article (100) comprising a first 3D printed region (110) having a first radiopacity and a second 3D printed region (120) having a second radiopacity, wherein the first radiopacity is greater than the second radiopacity. Also described is a method of forming the article (100).

A shielding material fabricating apparatus according to the present invention includes: a mixing unit mixing a resin and a carbon fiber; an extrusion unit extruding a mixture obtained in the mixing unit; and a cutting unit cutting an extrudate extruded from the extrusion unit. The shielding material fabricating apparatus according to the present invention is capable of: reducing a manufacturing time and promoting simplification of a process when fabricating an electromagnetic wave shielding material; improving performance in mixing the resin and the carbon fiber, thereby fabricating an electromagnetic wave shielding material having a superior shielding rate; and cutting a metal-plated carbon fiber and simultaneously making the resin impregnated therein without a delay in time, thereby making it possible to use a long fiber as it is in a non-pelletized state.

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.

An optical window is provided and includes a core layer, a cladding layer and an electromagnetic interference (EMI) layer interposed between the core and cladding layers.

A method of molding a metalized composite part. The method comprises: introducing particles comprising at least one metal into a gas stream; directing the gas stream toward a surface of a thermoplastic composite part, thereby depositing a metal layer on the composite part to form a metallized composite part; and molding the metallized composite part to introduce a bend without delamination of the metal layer from the metallized composite part.

Electromagnetic interference (EMI) shielding panels and associated methods. An EMI shielding panel includes a binding matrix material and electrically conductive elements distributed throughout the binding matrix material. The electrically conductive elements are aligned such that conductive element longitudinal axes of the electrically conductive elements are at least substantially parallel to a shielding axis of the EMI shielding panel. The electrically conductive elements are configured to at least partially attenuate an incident electromagnetic wave that is incident upon the EMI shielding panel. A method of forming an EMI shielding panel includes providing a shielding mixture that includes electrically conductive elements distributed throughout an uncured binding matrix material, magnetically aligning the electrically conductive elements, and curing the binding matrix material to form the EMI shielding panel.

A flowable liquid formulation for 3D printing is described. The formulation comprises from 0.1 to 25 wt. % radiopaque particles, wherein at least 50% by weight of the particles have a diameter of at most 100 nm. The formulation further comprises monomeric, oligomeric and/or polymeric precursors adapted for polymerization to form a solidified article. Also described is an article (100) formed by 3D printing, the article (100) comprising a first 3D printed region (110) having a first radiopacity and a second 3D printed region (120) having a second radiopacity, wherein the first radiopacity is greater than the second radiopacity. Also described is a method of forming the article (100).

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.