Abstract: A system (200) for monitoring conveyor belts is disclosed. The system (200) includes a sensor loop stack (110), RFID, a transmitter (104), a detector (106), RFID-readers and circuitry (108). The sensor loop stack incorporated and/or installed (inserted) into a conveyor belt (102). The transmitter (110) is configured to generate an electromagnetic field. The detector (106) is configured to measure an induced electric field from the sensor loop stack (110). The circuitry (108) is configured to detect damage of the conveyor belt based on the measured induced electromagnetic field.

Abstract: A system (200) for monitoring conveyor belts is disclosed. The system (200) includes a sensor loop stack (110), RFID, a transmitter (104), a detector (106), RFID-readers and circuitry (108). The sensor loop stack incorporated and/or installed (inserted) into a conveyor belt (102). The transmitter (110) is configured to generate an electromagnetic field. The detector (106) is configured to measure an induced electric field from the sensor loop stack (110). The circuitry (108) is configured to detect damage of the conveyor belt based on the measured induced electromagnetic field.

Abstract: A system for monitoring conveyor belts is disclosed. The system includes a printed inductive antenna loop, a transmitter, a detector, and circuitry. The antenna is printed on and/or installed (inserted) into a conveyor belt. The transmitter is proximate the printed antenna and is configured to generate an electromagnetic field. The detector is configured to measure an induced electric field from the printed inductive antenna loop. The circuitry is configured to detect damage of the conveyor belt based on the measured induced electromagnetic field.

Abstract: Heavy duty conveyor belts (1) having excellent resistance to high temperatures. These conveyor belts (1) can be repeatedly exposed to temperatures of greater than 200° C. or even 250° C. without compromising the strength or reliability of the belt while providing a greatly extended service life. The conveyor belts (1) may also be manufactured in a commercially viable and cost effective manner. The conveyor belts (1) generally include a reinforcement layer (3), a carry cover layer (2) disposed above the reinforcement layer (3), a pulley cover layer (4) disposed beneath the reinforcement layer (3), and the carry cover layer (2) is comprised of a fluoroelastomer. In some aspects, the conveyor belts (1) have a carry cover layer (2) which includes an outer surface layer (6) containing a fluoroelastomer and an inner layer (7) based upon an EPM elastomer or an EPDM elastomer.

Abstract: Heavy duty conveyor belts (1) having excellent resistance to high temperatures. These conveyor belts (1) can be repeatedly exposed to temperatures of greater than 200° C. or even 250° C. without compromising the strength or reliability of the belt while providing a greatly extended service life. The conveyor belts (1) may also be manufactured in a commercially viable and cost effective manner. The conveyor belts (1) generally include a reinforcement layer (3), a carry cover layer (2) disposed above the reinforcement layer (3), a pulley cover layer (4) disposed beneath the reinforcement layer (3), and the carry cover layer (2) is comprised of a fluoroelastomer. In some aspects, the conveyor belts (1) have a carry cover layer (2) which includes an outer surface layer (6) containing a fluoroelastomer and an inner layer (7) based upon an EPM elastomer or an EPDM elastomer.

Abstract: A hose includes an inner layer containing a fluoroelastomer, an outer layer containing one or more EPDM elastomer and EPM elastomer, and at least one textile reinforcement layer disposed between the inner layer and the outer layer. In some aspects, the at least one textile reinforcement layer is wound directly onto inner layer. Further, the textile reinforcement layer(s) may be an open braid textile which facilitates direct contact between the outer layer and the inner layer. In some cases, the fluoroelastomer has a fluorine content which is within the range of 64 weight percent to 71 weight percent. The fluoroelastomer may have repeat units which include at least two perflurorinated monomers and at least one cure site monomer, while in other cases, the fluoroelastomer has repeat units which include a perfluoroolefin monomer, a perfluorovinyl ether monomer, and a cure site monomer.

Abstract: The disclosure relates to a rubber mixture which contains at least one fluorine rubber and at least one active filler and carbon nanotubes. The rubber mixture has an additionally improved tear propagation resistance and, at the same time, improved processability. The disclosure further relates to a hose having at least the following layer structure: an inner layer as a barrier layer against aggressive media, which contains at least one fluorine rubber and at least one active filler and carbon nanotubes; and, an outer layer made of a cross-linked rubber mixture.

Abstract: The disclosure relates to a rubber mixture which contains at least one fluorine rubber and at least one active filler and carbon nanotubes. The rubber mixture has an additionally improved tear propagation resistance and, at the same time, improved processability. The disclosure further relates to a hose having at least the following layer structure: an inner layer as a barrier layer against aggressive media, which contains at least one fluorine rubber and at least one active filler and carbon nanotubes; and, an outer layer made of a cross-linked rubber mixture.

Abstract: A hose, in particular a charge-air hose, having an elastomer inner layer and at least one rubberized textile layer, wherein the at least one rubberized textile layer is directly wound onto the elastomer inner layer. The elastomer inner layer may be made from a fluoropolymer. The rubberized textile layer may be a woven fabric. Further, the rubberizing material of the rubberized textile ply may be based on a silicone rubber.

Abstract: The invention relates to a method for preparing halogen-free flameproof epoxy resins, in which a halogen-free epoxy resin is reacted with a polyfunctional aldehyde or ketone and a phosphinic acid derivative, wherein the phosphinic acid derivative contains at least one P—H-active structural unit of the formula ?PH(O) and is used in an amount equivalent to the polyfunctionality of the aldehyde or ketone, to a halogen-free flameproof epoxy resin obtainable by this method, to the use of the epoxy resin as a base material for the manufacture of printed circuit boards and printed circuits and to intermediates used to prepare the epoxy resins.

Abstract: The invention relates to a method for preparing halogen-free flameproof epoxy resins, in which a halogen-free epoxy resin is reacted with a polyfunctional aldehyde or ketone and a phosphinic acid derivative, wherein the phosphinic acid derivative contains at least one P—H-active structural unit of the formula ?PH(O) and is used in an amount equivalent to the polyfunctionality of the aldehyde or ketone, to a halogen-free flameproof epoxy resin obtainable by this method, to the use of the epoxy resin as a base material for the manufacture of printed circuit boards and printed circuits and to intermediates used to prepare the epoxy resins.