Abstract: A method for identifying a manipulated controller of a bus system of a vehicle is disclosed herein. The method includes transmitting a first message via the bus system by means of a first controller, and receiving the first message via the bus system by means of a second controller. The method further includes determining a message type of the received first message and determining a reference message by means of the second controller, wherein the reference message has a message type that corresponds to the determined message type of the first message. The method also includes determining a deviation of the first message from the reference message. When the first message deviates from the reference message, the method further includes identifying the first controller as the manipulated controller by means of the second controller, and providing an alarm message from the second controller to a server outside the vehicle.

Abstract: The invention relates to a method for producing flexible or elastic wood fiber insulating material products, having the following steps: -providing wood fibers which have been produced in a refiner. -providing multicomponent fibers with an inner and an outer component, said outer component melting or fusing at a melting temperature at which the inner component does not melt or fuse or has not yet melted or fused. -providing a mixture of wood fibers and multicomponent fibers. -heating the mixture to a temperature at which the outer component melts or fuses, and—connecting the multicomponent fibers together and to the wood fibers while cooling the mixture, wherein hardwood fiber bundles, in particular beechwood fiber bundles, are used as the wood fibers, and biodegradable multicomponent fibers are used as the multicomponent fibers.

Abstract: The invention relates to a method and an apparatus tor detecting density and/or thickness variations in materials transparent or partly transparent to infrared radiation, in which an examination object (1, 10) it arranged between an infrared source (3) and a thermographic camera (2), the examination object (1, 10) being irradiated by the inflated source (3) and the thermographic camera (2) arranged opposite the inflated source (3) detecting and evaluating the Infrared beams from the inflated source (3) passing through the examination object (1, 10).

Abstract: According to the invention, the bulk material is dropped down a drop section (5) for the purpose of separating the material, in order determine the temperature distribution of the bulk material very accurately and as completely as possible. Said drop section can be configured e.g. at the end of the conveyor belt (1). A thermographic measuring device (10, 11) is used to carry out spatially resolved measurement of the bulk material in a measuring area (15) of the drop section (5). The temperature distribution of the bulk material can then be determined from the measuring values (m). Local temperature increases in particular can be determined during this process, by comparison with a maximum allowable limit temperature, as can an inhomogeneity in the temperature distribution.

Abstract: A device for contactless testing of structural and/or surface defects of large-surface bodies, especially of slab-shaped materials includes a conveying device with an unsupported area; a source of heat arranged above the plane of conveyance and extending transversally to the direction of conveyance and which radiates heat in lines or strips onto the plane of conveyance; a thermographic camera having at least one camera line aligned transversally to the direction of conveyance and arranged above the plane of conveyance and after the source of heat in the direction of conveyance; and a computer connected to the camera that has a monitor and generates a separate heat image pattern from every camera line.

Abstract: A device for contactless testing of structural and/or surface defects of large-surface bodies, especially of slab-shaped materials includes a conveying device with an unsupported area; a source of heat arranged above the plane of conveyance and extending transversally to the direction of conveyance and which radiates heat in lines or strips onto the plane of conveyance; a thermographic camera having at least one camera line aligned transversally to the direction of conveyance and arranged above the plane of conveyance and after the source of heat in the direction of conveyance; and a computer connected to the camera that has a monitor and generates a separate heat image pattern from every camera line.