Provided is an expansive refractory material that not only has excellent fire resistance but also can provide a heat insulating function for protecting a content by expanding to form a heat insulating layer when the refractory material is brought close to a heat source or comes into contact with flame. The refractory material at least includes: discontinuous reinforcing fibers having a thermal conductivity of 4 W/(m.Math.K) or higher; and a flame-retardant thermoplastic resin, wherein the discontinuous reinforcing fibers are dispersed in the refractory material. The refractory material has a post-expansion porosity of 30% or higher.

A system may include a controller configured to cause a capacitance probe to subject a material to a first electric signal having a first frequency and determine a first capacitance of the material at the first frequency. The controller is configured to cause the capacitance probe to subject the material to a second electric signal at a second frequency and determine a second capacitance of the material at the second frequency. The material includes at least a first constituent phase and a second constituent phase. The first constituent phase and the second constituent phase have substantially similar dielectric constants at the first frequency and substantially different dielectric constants at the second frequency. The controller is further configured to determine a porosity of the material based on the first capacitance and determine a relative phase composition of the first constituent phase and the second constituent phase based on the second capacitance.

The purpose of the present invention is to provide a liquid permeable body comprising a porous composite that has different liquid permeabilities between in the in-plane direction and in the out-of-plane direction as well as excellent mechanical properties. The liquid permeable body comprises a porous composite having a structure in which discontinuous reinforcing fibers are dispersed; the dispersed discontinuous reinforcing fibers are bonded with a thermoplastic resin at at least an intersection thereof; voids of continuous openings form a void content of from 30 to 90%; an average value of fiber orientation angles is from 0 to 40 in an in-plane direction of the discontinuous reinforcing fibers; and an average value of fiber orientation angles is from 0 to 25 in an out-of-plane direction of the discontinuous reinforcing fibers.

A method for forming a shaped part is provided. The method comprises melt blending a first polymer composition and a second polymer composition to form a molten blend, wherein the first polymer composition comprises a plurality of long inorganic fibers distributed within a first polymer matrix and the second polymer composition comprises a plurality of cellulosic fibers distributed within a second polymer matrix. The molten blend is injected into a mold cavity and cooled to form the shaped part.

A pultruded article, comprising a fiber phase in the pultruded article and polymeric matrix in the pultruded article, the polymeric matrix impregnated within the fiber phase prior to pultruding the pultruded article; wherein the pultruded article forms at least a portion of a carrier adapted for use as a baffle, a structural reinforcement of both.

A system may include a controller configured to cause a capacitance probe to subject a material to a first electric signal having a first frequency and determine a first capacitance of the material at the first frequency. The controller is configured to cause the capacitance probe to subject the material to a second electric signal at a second frequency and determine a second capacitance of the material at the second frequency. The material includes at least a first constituent phase and a second constituent phase. The first constituent phase and the second constituent phase have substantially similar dielectric constants at the first frequency and substantially different dielectric constants at the second frequency. The controller is further configured to determine a porosity of the material based on the first capacitance and determine a relative phase composition of the first constituent phase and the second constituent phase based on the second capacitance.

A fiberglass reinforced aerogel composite may include coarse glass fibers, glass microfibers, aerogel particles, and a binder. The coarse glass fibers may have an average fiber diameter between about 8 m and about 20 m. The glass microfibers may have an average fiber diameter between about 0.5 m and about 3 m. The glass microfibers may be homogenously dispersed within the coarse glass fibers. The aerogel particles may be homogenously dispersed within the coarse glass fibers and the glass microfibers. The fiberglass reinforced aerogel composite may include between about 50 wt. % and about 75 wt. % of the aerogel particles. The binder bonds the coarse glass fibers, the glass microfibers, and the aerogel particles together.

A stabilized reinforcing textile fabric including at least one uni-directional reinforcing yarn (A) layer and a plurality of stitching yarns. The plurality of stitching yarns are meltable thermoplastic yarns (B) functioning as a stabilizing resin. The at least one uni-directional reinforcing yarn is includes a carbon fiber, a glass fiber, an aramid fiber, and a natural fiber, or a combination thereof. The meltable thermoplastic stitching yarns include polyamides, polyolefins, polyphthalamides, polyphenylene sulfide, polysulfone, polyether sulfone, polyarylene sulfide, fluoropolymer, polyacetal, polycarbonate, polyether ketone, polyether ether ketone, polyimide, polyether imide, polyarylene ether sulfone, styrenic polymer, polyesters or a combination thereof.

To provide a novel material that maintains suppleness which is the advantage of a material using fibers and has a low thermal shrinkage ratio, and a method for producing the material, a partially welded material using the material, a composite material, and a method for producing a molded product.

A material including: a first region, a fiber region, and a second region continuously in a thickness direction; the first region and the second region being each independently a resin layer including from 20 to 100 mass % of a thermoplastic resin component and from 80 to 0 mass % of reinforcing fibers; the fiber region including from 20 to 100 mass % of thermoplastic resin fibers and from 80 to 0 mass % of reinforcing fibers; the thermoplastic resin component included in the first region and the thermoplastic resin component included in the second region each independently having a crystallization energy during temperature increase of 2 J/g or greater, measured by differential scanning calorimetry; and the thermoplastic resin fibers included in the fiber region having a crystallization energy during temperature increase of less than 1 J/g, measured by differential scanning calorimetry; wherein the crystallization energy during temperature increase is a value measured by using a differential scanning calorimeter (DSC) in a nitrogen stream while heating is performed from 25 C. to a temperature that is 20 C. higher than a melting point of the thermoplastic resin component or the thermoplastic resin fibers at a temperature increase rate of 10 C./min.

To provide a thermoplastic resin fiber to which a dispersant is attached, which can effectively disperse carbon fibers.

A thermoplastic resin fiber to which a dispersant containing a random copolymer (A) of glycidyl ether and an alkylene oxide is attached in an amount of 0.1 to 20% by mass based on a total mass of thermoplastic resin fibers to which a dispersant is not attached.