Abstract: An integrated glazing with a data transponder embedded between layers of glass is disclosed. The data transponder stores and processes data. The integrated glazing also includes a display unit including display elements disposed between layers of glass, communicating with the data transponder. The integrated glazing may comprise a data channel, a power channel, antenna and chip. An intelligent system is also disclosed including the integrated glazing, a reader device and a control system. The reader device is communicably coupled to the integrated glazing to generate signals based on the received data. The control system is communicably coupled to the integrated glazing and the reader device to process signals received from the reader device and perform pre-defined operations in response to the instructions and received signals.

Abstract: An abrasive article includes an abrasive body having a bond material, abrasive particles contained within the bond material, and an electronic assembly coupled to the abrasive body, wherein the electronic assembly comprises at least one electronic device. In an embodiment, the electronic assembly is coupled to the abrasive body in a tamper-proof manner.

Abstract: An abrasive article includes an abrasive body having a bond material, abrasive particles contained within the bond material, and an electronic assembly coupled to the abrasive body, wherein the electronic assembly comprises at least one electronic device. In an embodiment, the electronic assembly is coupled to the abrasive body in a tamper-proof manner.

Abstract: The present application relates to systems and methods for obtaining real-time abrasion data. An example computer-implemented method could include receiving, at a computing device, sensor data from one or more sensors. The one or more sensors are disposed in proximity to an abrasive product or a workpiece associated with the abrasive product. The one or more sensors are configured to collect abrasion operational data associated with an abrasive operation involving the abrasive product or the workpiece. The computer-implemented method could further include training, based on the sensor data, a machine learning system to determine product specific information of the abrasive product and/or workpiece specific information. The computer-implemented method could also include providing the trained machine learning system using the computing device.

Abstract: An optimized display system for a vehicle using a glass assembly. The system includes a power source coupled to the processing unit for providing an input DC voltage. The processing unit is coupled to the power source. The processing unit is configured to receive input. The processing unit generates a command signal to interactively control a display unit in response to at least one input. A convertor is coupled to the processing unit. The convertor is configured to generate at least one of an output AC voltage or output DC voltage based on the command signal. The display unit includes one or more illumination devices sandwiched in the glass assembly.

Abstract: A laminated glazing includes a first substrate having an outer face and an inner face, one or more interlayers disposed on the inner face of the first substrate, a second substrate disposed on the interlayer and at least one data transponder device. The date transponder device includes an antenna and an integrated circuit that is provided between the first substrate and the second substrate Optionally, one or more heating elements is/are provided between the first substrate and the second substrate and spaced around the data transponder device at a pre-defined distance for rapidly heating the antenna the data transponder.

Abstract: An interactive system for a vehicle using a display unit integrated on the windshield. The system receives user inputs and control the display unit based on the user input is disclosed. The system includes a display unit, which is present on the windshield of the rear window glazing, side window glazing or roof glazing of a vehicle. The display unit is composed of one or more illumination devices sandwiched between a first substrate and a second substrate of the glass assembly. The display unit is configured to display patterns, emoticons with varying intensity of illumination, frequency and color. The system further includes a sensor unit with a plurality of sensors that monitors condition and status of the vehicle. The processing unit is configured to control the display unit based on user actions and data received from the data retrieving unit.

Abstract: A coated laminated glazing providing improved readability for data transponder device is disclosed. The coated laminated glazing includes a surface coating layer provided on at least one of face two or face three of the laminated glazing and having an etched area selectively provided on the surface coating layer. The coated laminated glazing includes a data transponder or antenna positioned below the etched area and sandwiched between a first substrate and a second substrate of the laminated glazing. Alternatively, the coated laminated glazing is fixed in close proximity to the etched area to face 1 or face 4 of the laminated glazing. The etched area is characterized by a plurality of disjoint patterns to provide improved data readability through RF transparency. The coated laminated glazing further includes one or more interlayers disposed between the first substrate and the second substrate.

Abstract: An integrated glazing with a data transponder embedded between layers of glass is disclosed. The data transponder stores and processes data. The integrated glazing also includes a display unit including display elements disposed between layers of glass, communicating with the data transponder. The integrated glazing may comprise a data channel, a power channel, antenna and chip. An intelligent system is also disclosed including the integrated glazing, a reader device and a control system. The reader device is communicably coupled to the integrated glazing to generate signals based on the received data. The control system is communicably coupled to the integrated glazing and the reader device to process signals received from the reader device and perform pre-defined operations in response to the instructions and received signals.

Abstract: An automobile glazing defogger includes of one or more primary defogger coil in a predetermined pattern, design or other representation and a secondary defogger coil covering the rest of the automobile glazing. The primary defogger coil is heated faster to a specified temperature to provide faster defogging than the secondary defogger coil and to indicate the working of the defogger.

Abstract: An abrasive article includes a body and an electronic assembly coupled to the body, the electronic assembly including an electronic device, and a first portion between the body and the communication device, the first portion having a material of an average relative magnetic permeability of not greater than 15.

Abstract: The present application relates to systems and methods for obtaining real-time abrasion data. An example computer-implemented method could include receiving, at a computing device, sensor data from one or more sensors. The one or more sensors are disposed in proximity to an abrasive product or a workpiece associated with the abrasive product. The one or more sensors are configured to collect abrasion operational data associated with an abrasive operation involving the abrasive product or the workpiece. The computer-implemented method could further include training, based on the sensor data, a machine learning system to determine product specific information of the abrasive product and/or workpiece specific information. The computer-implemented method could also include providing the trained machine learning system using the computing device.

Abstract: A laminated glazing includes a first substrate having an outer face and an inner face, one or more interlayers disposed on the inner face of the first substrate, a second substrate disposed on the interlayer and at least one data transponder device. The date transponder device includes an antenna and an integrated circuit that is provided between the first substrate and the second substrate Optionally, one or more heating elements is/are provided between the first substrate and the second substrate and spaced around the data transponder device at a pre-defined distance for rapidly heating the antenna the data transponder.

Abstract: An abrasive article can include a wear detection sensor embedded within the abrasive body or extending along an exterior surface of the abrasive body. The wear detection sensor can include at least one conductive lead and be designed to create one or more wear signals corresponding to the wear stage of the abrasive body. The at least one conductive lead can be coupled to a logic device, which may control the wear detection sensor and register the wear signal(s).

Abstract: A thermal conditioning system for an off-shore wind turbine. The thermal conditioning system has an insulating structure that reduces the thermal losses by convection of treated air circulating through a duct inside the tower, from the base-level of the wind turbine to the nacelle structure. The treated air is supplied by an air-treatment system located at the base level of the wind turbine. In the insulating structure an insulating material of a greater thermal conductivity than the treated air is provided, and a plurality of voids is arranged between the insulating material so that air flow between the voids is prevented by the insulating material.

Abstract: An abrasive article includes an abrasive body having a bond material, abrasive particles contained within the bond material, and an electronic assembly coupled to the abrasive body, wherein the electronic assembly comprises at least one electronic device. In an embodiment, the electronic assembly is coupled to the abrasive body in a tamper-proof manner.

Abstract: A thermal conditioning system for an off-shore wind turbine is provided. The thermal conditioning system comprises channels for circulating ambient air from an inlet area located in the outside of the wind turbine nacelle to an outlet area located in the outside of the wind turbine preventing that the ambient air enters inside the wind turbine nacelle. The ambient air channels are arranged to cool conductively or convectively the air inside the wind turbine nacelle.

Abstract: A thermal conditioning system for an off-shore wind turbine is provided. The thermal conditioning system comprises an insulating structure that reduces the thermal losses by convection of a treated air circulating through a duct inside the tower, from the base-level to the nacelle structure, for thermal conditioning purposes. The treated air is supplied by an air-treatment system located at the base level of the off-shore wind turbine. The insulating structure comprises insulating material of a greater thermal conductivity than the air and a plurality of voids arranged between insulating material so that air flow between said voids is prevented.

Abstract: An in-built energy conservation device has been described for offshore turbines. The energy conservation device includes a heat engine and a generator. The heat engine extracts a portion of heat energy from a coolant flowing the through the wind turbine. The heat engine further converts the heat energy into the mechanical energy. The generator converts the mechanical energy into the electrical energy. The electrical energy is further used for the operation of at least one of a heat exchanger unit and an air treatment plant present in the offshore wind turbine. The energy conservation device further includes an inlet. The inlet allows the passage of treated air through the energy conservation device for thermal conditioning of the treated air. The thermal conditioning makes up for the thermal losses of the treated air while passing though a plurality of flow lines within a wind turbine tower.

Abstract: Method and system for predictive maintenance of switch contactors, preferably of converters in wind turbine generators, comprising measuring the temperature of an element located outside a switch contactor enclosure in contact with the contactors inside the enclosure, and calculating said switch contactor temperature based on said element temperature and predetermined correction values, and measuring the current through the switch contactor, and calculating a switch contact resistance value based on said calculated switch contact temperature and said measured current through the contactor, and determining a maintenance parameter of said switch contact by comparing said calculated switch contact resistance value to a predetermined nominal contact resistance value.