Abstract: The present invention provides an optical fire sensor device and a corresponding fire detection method. The optical fire sensor device is equipped with an optical particle detection unit (10), which is configured to ascertain measured values of a particle number in a measurement volume range (FA) as a function of a particle size in a predetermined particle size range and/or as a function of a particle speed in a predetermined particle speed range, a fire detection unit (20), which is configured to ascertain respective distributions of the measured values and to compare at least one parameter of the ascertained distributions to at least one predetermined criterion. The fire detection unit (20) is configured to detect a fire (B) in consideration of the comparison. An alarm unit (30, 40) is used to output an alarm signal in response to the detection of the fire (B) by the fire detection unit (20).

Abstract: The present invention provides an optical fire sensor device and a corresponding fire detection method. The optical fire sensor device is equipped with an optical particle detection unit (10), which is configured to ascertain measured values of a particle number in a measurement volume range (FA) as a function of a particle size in a predetermined particle size range and/or as a function of a particle speed in a predetermined particle speed range, a fire detection unit (20), which is configured to ascertain respective distributions of the measured values and to compare at least one parameter of the ascertained distributions to at least one predetermined criterion. The fire detection unit (20) is configured to detect a fire (B) in consideration of the comparison. An alarm unit (30, 40) is used to output an alarm signal in response to the detection of the fire (B) by the fire detection unit (20).

Abstract: A fire monitoring system 1 having at least a first and a second monitoring camera 4, 5 for outputting monitoring images 4.a; 5.1, wherein the viewing fields 6, 7 of the first and the second monitoring camera 4, 5 overlap in a common monitoring region 8, having an evaluation device 9 for identifying a fire 2, 3 in the monitoring images 4.1, 5.1 is constructed, wherein the evaluation device 9 is constructed to output positional information of the fire 2, 3 by way of evaluating the monitoring images 4.a, 5.1.

Abstract: A photoelectric smoke detector 1 for detecting smoke particles 4 is disclosed, the smoke detector 1 comprising: a light emitting element 5, a light receiving element 6 for receiving light 8 emitted by the light emitting element 5 and scattered by the smoke particles 4 and for outputting a detection signal 12 obtained by photoelectrical converting the received light 10, 11, an amplifier circuit 13 for amplifying the detection signal 12 and providing an amplified output signal 14, wherein the amplified output signal 14 may be divided into an offset-signal 20 and an amplified detection signal 21, whereby the photoelectric smoke detector 1 is adapted to operate in a pulsed mode, so that the detection signal 12 comprises high-frequency components, whereby the amplified detection signal 21 is determined by high-frequency components of the detection signal 12 and that the offset-signal 20 is determined by low-frequency components of the detection signal 12 and/or by low-frequency components of at least an intermedia

Abstract: Fire detector installations comprise fire detectors as sensor devices for detecting fires, smoke, flames or other signs of fire, and are used in both public buildings, such as schools or museums, and in private buildings. The invention relates to a detection device (1) for detecting fires and/or signs of fire in an area to be monitored, said detection device comprising an image-producing sensor element (2) for emitting image data, and an optical element (3) mounted upstream of the sensor element (2), which together form a camera system (6) for monitoring the area to be monitored. The detection device also comprises an evaluation element (8) designed to detect fires or signs of fire in the area to be monitored by evaluating the image data.

Abstract: A fire monitoring system 1 having at least a first and a second monitoring camera 4, 5 for outputting monitoring images 4.a; 5.1, wherein the viewing fields 6, 7 of the first and the second monitoring camera 4, 5 overlap in a common monitoring region 8, having an evaluation device 9 for identifying a fire 2, 3 in the monitoring images 4.1, 5.1 is constructed, wherein the evaluation device 9 is constructed to output positional information of the fire 2, 3 by way of evaluating the monitoring images 4.a, 5.1.

Abstract: A photoelectric smoke detector 1 for detecting smoke particles 4 is disclosed, the smoke detector 1 comprising: a light emitting element 5, a light receiving element 6 for receiving light 8 emitted by the light emitting element 5 and scattered by the smoke particles 4 and for outputting a detection signal 12 obtained by photoelectrical converting the received light 10, 11, an amplifier circuit 13 for amplifying the detection signal 12 and providing an amplified output signal 14, wherein the amplified output signal 14 may be divided into an offset-signal 20 and an amplified detection signal 21, whereby the photoelectric smoke detector 1 is adapted to operate in a pulsed mode, so that the detection signal 12 comprises high-frequency components, whereby the amplified detection signal 21 is determined by high-frequency components of the detection signal 12 and that the offset-signal 20 is determined by low-frequency components of the detection signal 12 and/or by low-frequency components of at least an intermedia

Abstract: Fire detector installations comprise fire detectors as sensor devices for detecting fires, smoke, flames or other signs of fire, and are used in both public buildings, such as schools or museums, and in private buildings. The invention relates to a fire detector device (1) for detecting fires and or signs of fire in an area to be monitored, said fire detector device comprising a camera element (2) for recording image data in the area to be monitored, and an evaluation element (7) designed to detect a fire or signs of fire by evaluating the image data. The fire detector device (1) is designed as a multi-criteria detector and comprises at least one other sensor element (3, 12, 13, 14) for fire detection.

Abstract: Fire detector installations comprise fire detectors as sensor devices for detecting fires, smoke, flames or other signs of fire, and are used in both public buildings, such as schools or museums, and in private buildings. The invention relates to a detection device (1) for detecting fires and/or signs of fire in an area to be monitored, said detection device comprising an image-producing sensor element (2) for emitting image data, and an optical element (3) mounted upstream of the sensor element (2), which together form a camera system (6) for monitoring the area to be monitored. The detection device also comprises an evaluation element (8) designed to detect fires or signs of fire in the area to be monitored by evaluating the image data.

Abstract: A detection device for detecting fires and/or fire features in a monitoring region along a monitoring path includes a camera device that is located and/or may be located in the monitoring region in order to generate image data, an evaluation device which is designed to detect fire and/or fire features in the monitoring range by evaluating the image data, in the case of which the detection device may be used to select a section of the monitoring range in which the evaluation is carried out, and the detection device is designed such that the monitoring range section has a maximum viewing angle alpha of less than 5°, preferably less than 3°, and, in particular less than 1°.

Abstract: The cleaning and exchange of components of the hearing aid which is necessary at regular intervals due to the conventional contamination is uncomfortable and expensive. The housing (G) and any protective devices (K) which are to protect from contamination, are provided with a dirt-resistant layer. In this way, the dirt adheres less strongly to the hearing aid, so that if necessary it can be removed by means of tapping.

Abstract: The microphones used in hearing devices normally possess different characteristic lines that are to be adapted to one another. For this purpose, the amplitude of an output signal of a first microphone and the amplitude of an output signal of a second microphone are measured. The output signal of the first microphone is subsequently filtered dependent on both measured amplitudes, such that the difference between the two output signals is reduced. One of the two microphones hereby serves as a reference, and an absolute normalization can be foregone.

Abstract: In a hearing aid and method for automatically switching to a telephone mode, for automatically detecting a telephone situation for the wearer given a binaural supply, the difference between the levels of the input signals of the two hearing devices is measured and compared with at least one threshold value. If the difference in levels drops below or exceeds the threshold value, the respective hearing device is switched to the telephone mode.

Abstract: The cleaning and exchange of components of the hearing aid which is necessary at regular intervals due to the conventional contamination is uncomfortable and expensive. The housing (G) and any protective devices (K) which are to protect from contamination, are provided with a dirt-resistant layer. In this way, the dirt adheres less strongly to the hearing aid, so that if necessary it can be removed by means of tapping.

Abstract: In a hearing aid and method for automatically switching to a telephone mode, for automatically detecting a telephone situation for the wearer given a binaural supply, the difference between the levels of the input signals of the two hearing devices is measured and compared with at least one threshold value. If the difference in levels drops below or exceeds the threshold value, the respective hearing device is switched to the telephone mode.

Abstract: The microphones used in hearing devices normally possess different characteristic lines that are to be adapted to one another. For this purpose, the amplitude of an output signal of a first microphone and the amplitude of an output signal of a second microphone are measured. The output signal of the first microphone is subsequently filtered dependent on both measured amplitudes, such that the difference between the two output signals is reduced. One of the two microphones hereby serves as a reference, and an absolute normalization can be foregone.