Abstract: The present invention relates to a compound of formula (I) capable of inhibiting plasmin activity and having blood coagulation and hemostasis activity, and a pharmaceutically acceptable salt, hydrate, isomer, prodrug and mixture thereof, wherein R1 to R3 are as defined in the description.

Abstract: A rhein amide derivative and a preparation method and use thereof, and a drug for treating hepatocellular carcinoma (HCC) caused by a specific expression of RECQL4. The rhein amide derivative has a structure shown in any one of formulas I to IV. The rhein amide derivative has a relatively strong inhibitory effect on proliferation of HCC cells SNU-398 with RECQL4 high expression. Development of a novel anti-cancer drug for RECQL4 high expression-caused HCC and clinical personalized treatment of the RECQL4 high expression-caused HCC.

Abstract: An electrical connector including a housing defining an interior cavity and extending from a mounting end to an engagement end, and at least one signal component disposed within the interior cavity of the housing. The housing is formed from a conductive composite material and engages the at least one signal component to shield the interior cavity.

Abstract: An electrical connector including a housing defining an interior cavity and extending from a mounting end to an engagement end, and at least one signal component disposed within the interior cavity of the housing. The housing is formed from a conductive composite material and engages the at least one signal component to shield the interior cavity.

Abstract: A composite formulation and a composite article are provided. The composite article includes at least two layers of a composite formulation including a polymer matrix and conductive particles distributed within the polymer matrix, the conductive particles forming, by volume, between 20% and 50% of the composite formulation. The conductive particles in each of the at least two layers include at least one morphology selected from the group consisting of fibrous, dendritic, and flake, and the morphology of the conductive particles in one of the at least two layers differs from the morphology of the conductive particles in another one of the at least two layers. The composite formulation includes a polymer matrix and between 30% and 45%, by volume, tin-coated copper conductive particles at a copper/tin ratio of between 3/1 and 3/2, the conductive particles including at least two morphologies selected from the group consisting of fibrous, dendritic, and flake.

Abstract: Processes of applying conductive composites on flexible materials, transfer assemblies, and garments including conductive composites are disclosed. The processes include positioning the conductive composite relative to the flexible material, the conductive composite having a resin matrix and conductive filler, and heating the conductive composite with an iron thereby applying the conductive composite directly onto the flexible material. Additionally or alternatively, the processes include positioning the conductive composite relative to the clothing, and heating the conductive composite thereby applying the conductive composite on the clothing. The garments include the flexible material and the conductive composite positioned directly on the flexible material. The transfer assembly has the conductive composite on a transfer substrate.

Abstract: A method of forming a composite article, wherein the method includes providing a composite formulation, the composite formulation including a polymer matrix and at least one additive distributed in the polymer matrix at a concentration of between 10% and 50%, by volume, the at least one additive having a molar percentage of carbon that is equal to or less than 90%, feeding the composite formulation to a printing head of an additive manufacturing device, heating the composite formulation to form a heated composite formulation, extruding the heated composite formulation through a nozzle in the printing head, and depositing the heated composite formulation onto a platform to form the composite article. Also provided is a composite article produced from a composite formulation having at least one additive distributed in a polymer matrix.

Abstract: A composite formulation and a composite article are provided. The composite article includes at least two layers of a composite formulation including a polymer matrix and conductive particles distributed within the polymer matrix, the conductive particles forming, by volume, between 20% and 50% of the composite formulation. The conductive particles in each of the at least two layers include at least one morphology selected from the group consisting of fibrous, dendritic, and flake, and the morphology of the conductive particles in one of the at least two layers differs from the morphology of the conductive particles in another one of the at least two layers. The composite formulation includes a polymer matrix and between 30% and 45%, by volume, tin-coated copper conductive particles at a copper/tin ratio of between 3/1 and 3/2, the conductive particles including at least two morphologies selected from the group consisting of fibrous, dendritic, and flake.

Abstract: Coil assembly including a flux-control body having a magnetic material and a body side. The flux-control body includes a shield wall that defines a coil channel of the flux-control body that opens along the body side to an exterior of the flux-control body. The coil assembly also includes an electrical conductor positioned within the coil channel. The electrical conductor forms a power-transfer coil having co-planar windings that are configured to generate a magnetic flux within a spatial region that is adjacent to the body side. Adjacent windings are separated by the shield wall of the flux-control body. The shield wall controls a distribution of the magnetic flux experienced within the spatial region.

Abstract: Processes of applying conductive composites on flexible materials, transfer assemblies, and garments including conductive composites are disclosed. The processes include positioning the conductive composite relative to the flexible material, the conductive composite having a resin matrix and conductive filler, and heating the conductive composite with an iron thereby applying the conductive composite directly onto the flexible material. Additionally or alternatively, the processes include positioning the conductive composite relative to the clothing, and heating the conductive composite thereby applying the conductive composite on the clothing. The garments include the flexible material and the conductive composite positioned directly on the flexible material. The transfer assembly has the conductive composite on a transfer substrate.

Abstract: Cable shielding assemblies and processes of producing cable shielding assemblies are described. The cable shielding assemblies include a conductor and a conductive composite shield extending around at least a portion of the conductor, the conductive composite shield having a non-conductive matrix and conductive particles within the non-conductive matrix. The conductive composite shield has a resistivity of less than 0.05 ohm·cm. The processes of producing cable shielding assembles include positioning the conductive composite shield. The positioning is at least partially around a conductor, at least partially around a dielectric material, at least partially surrounded by a jacket material, or a combination thereof.

Abstract: A conductive composite formulation and an article at least partially formed from a conductive composite formulation are disclosed. The conductive composite formulation includes a polymer matrix and a colorant blended with the polymer matrix. The conductive composite formulation and the article each have a compound resistivity of between 0.0005 ohm·cm and 0.2 ohm·cm.

Abstract: An article and process are described. The article includes a conductive heat-recoverable composite shield or a conductive heat-recovered composite shield formed from a conductive heat-recoverable composite shield. The conductive composite shield and/or the conductive heat-recovered composite shield formed from a conductive heat-recoverable composite shield comprises a non-conductive matrix and conductive particles within the non-conductive matrix. The article has a resistivity of less than 0.05 ohm·cm. A process of producing the conductive heat-recovered composite shield includes extruding the conductive heat-recoverable composite shield and heating the conductive heat-recoverable composite shield thereby forming the conductive heat-recovered composite shield.

Abstract: A composite formulation and composite product are disclosed. The composite formulation includes a polymer matrix, tin-containing particles blended within the polymer matrix at a concentration, by weight, of at least 25%, copper-containing particles blended within the polymer matrix at a concentration, by weight, of at least 40%, and one or both of solder flux and density-lowering particles blended into the polymer matrix. The tin-containing particles and the copper-containing particles have one or more intermetallic phases from metal-metal diffusion of the tin-containing particles and the copper-containing particles being blended at a temperature within the intermetallic annealing temperature range for the tin-containing particles and the copper-containing particles.

Abstract: A composite formulation and electrical component are disclosed. The composite formulation includes a polymer matrix having at least 15% crystallinity and process-aid-treated copper-containing particles blended with the polymer matrix including higher aspect ratio particles and lower aspect ratio particles. The higher ratio particles and the lower ratio particles produce a decreased percolation threshold for the composite formulation when processed by extrusion or molding, the decreased percolation threshold being compared to a similar composition that fails to include the first particle and the second particles. The electrical component includes a composite product produced from the composite formulation and is selected from the group consisting of an antenna, electromagnetic interference shielding device, a connector housing, and combinations thereof.

Abstract: A multi-functional electric cooker includes a heating boiler body (1) and a cover (2). The cooker also includes a rice soup collecting container (3) which is mounted between the heating boiler body (1) and the cover (2), a sealing ring (7) which is set between the rice soup collecting container (3) and the heating boiler body (1), and a rice soup sucker (6). An opening of one end of the sucker is located at the bottom of the rice soup collecting container (3) and the height of the opening is adjusted along with the amount of the rice in the heating boiler body. An opening of the other end of the sucker is located in the rice soup collecting container (3).

Abstract: A multi-functional electric cooker comprises a heating boiler body (1) and a cover (2). The cooker also comprises a rice soup collecting container (3) which is mounted between the heating boiler body (1) and the cover (2), a sealing ring (7) which is set between the rice soup collecting container (3) and the heating boiler body (1), and a rice soup sucker (6). An opening of one end of the sucker is located at the bottom of the rice soup collecting container (3) and the height of the opening is adjusted along with the amount of the rice in the heating boiler body. An opening of the other end of the sucker is located in the rice soup collecting container (3).