Patent application number | Description | Published |
20120132811 | SCINTILLATOR-PHOTOSENSOR SANDWICH AND RADIATION DETECTOR AND PRODUCTION METHOD THEREFOR, EMBODYING SAME - In a method to produce a scintillator-photosensor sandwich for use in a pixel-resolving radiation detector for ionizing radiation, either a scintillator layer or a photosensor layer can respectively be the first and second function layers (alternatively). A transfer adhesive tape carries an adhesive layer having an exposed first side and a second side covered by protective film. The exposed side of the adhesive layer is applied onto a first of the function layers. A first lamination of the adhesive layer including the protective film onto the first function layer is implemented. The protective film is removed. A second of the function layers is then placed in contact with the second side of the adhesive layer that is situated on the first of the function layers. A second lamination of the two function layers with the adhesive layer situated between them is implemented. | 05-31-2012 |
20120132812 | METHOD TO PRODUCE A SCINTILLATOR-PHOTOSENSOR SANDWICH, SCINTILLATOR-PHOTOSENSOR SANDWICH, AND RADIATION DETECTOR - In a method to produce a scintillator-photosensor sandwich, as well as a scintillator-photosensor sandwich and a radiation detector with such a scintillator-photosensor sandwich, the scintillator-photosensor sandwich is generated by gluing a first support frame onto an adhesive layer (covered on at least one side with a second protective film on the side facing the adhesive layer, the first frame having a size that (in terms of area) surrounds the scintillator-photosensor sandwich to be produced. The first support frame is placed onto a flat base that supports a first function layer (either a scintillator layer or a photosensor layer). The adhesive layer supported on the first support frame and the first function layer are laminarly assembled. The second protective film is removed from the adhesive layer and a second function layer (the other of the scintillator layer or the photosensor layer not used as the first function layer) is assembled with the first function layer with the interposed adhesive layer. | 05-31-2012 |
20120132816 | METHOD TO PREPARE A SCINTILLATOR LAYER FOR APPLICATION ONTO A PHOTOSENSOR LAYER TO PRODUCE AN X-RAY DETECTOR OR ELEMENT THEREOF - A scintillator layer is applied onto a photosensor layer to produce an x-ray detector or an x-ray detector element for imaging detection of ionizing radiation. The production process is improved by, in the production of the scintillator layer, an adhesive layer with a protective layer is applied onto the scintillator layer. This can occur layer by layer or a transfer adhesive tape that already includes the protective layer as a protective film can also be used. | 05-31-2012 |
20130176025 | AVOIDANCE OF SUSCEPTIBILITY ARTIFACTS IN MAGNETIC RESONANCE MEASUREMENTS VIA TARGETED ADDITION OF RECYCLED MATERIALS IN PLASTIC PARTS - Susceptibility artifacts are significantly reduced or avoided in a magnetic resonance image by producing one or more components of a magnetic resonance system from plastic material having a targeted addition or recycled plastic material. | 07-11-2013 |
Patent application number | Description | Published |
20090207006 | Method for Functionally Testing an Ultrasonic Sensor - A method for functionally testing an ultrasonic sensor in which at least one additional ultrasonic sensor transmits an ultrasound signal, and a functioning of the first sensor is ascertained when the amplitude of the signal transmitted by the first sensor without being reflected off of an external obstacle exceeds a predefined, variable limit value. | 08-20-2009 |
20090251990 | Method for Functionally Testing an Ultrasonic Sensor - A method for functionally testing an ultrasonic sensor on a motor vehicle in which, in a test operating mode, an ultrasonic signal is emitted whose magnitude is large enough that under conventional conditions this ultrasonic signal is reflected by a ground surface in front of the vehicle and is received again. In this way, it can easily be determined that the ultrasonic sensor is functioning properly. | 10-08-2009 |
20100067324 | METHOD FOR CALIBRATING AN ULTRASONIC SENSOR AND ULTRASONIC DISTANCE MEASURING APPARATUS - In a method for calibrating an ultrasonic sensor, and an ultrasonic distance-measuring device a crosstalk signal is transmitted from a first ultrasonic sensor to a second ultrasonic sensor. The amplitude of the crosstalk signal is compared with a stored value, and the sensitivity of the sensor is set as a function of comparison. | 03-18-2010 |
20100329080 | SENSOR FUNCTION FOR CONTROLLING AT A VARIABLE TRANSMISSION FREQUENCY FOR THE PURPOSE OF DETECTING CONTAMINATION - In a method for functional testing of a mechanical vibration sensor, a vibration signal is generated on the vibration component of the vibration sensor with the aid of a periodic excitation signal, the frequency of which excitation signal is varied, and a post-vibration process of the vibration component of the vibration sensor is analyzed once the excitation signal has been switched off. | 12-30-2010 |
20120017684 | SENSOR DEVICE AND METHOD FOR OPERATING A SENSOR DEVICE - A sensor device described having a sensor, in particular an ultrasound sensor, having a generating and detecting arrangement to generate and detect waves, in particular sound waves, the detection arrangement converting received waves into electric signals, and the electric signals being evaluable by an evaluation unit. A function-monitoring device is configured to determine an impedance characteristic curve of the sensor as a function of an excitation frequency is provided. Also described is a method for operating the sensor device. | 01-26-2012 |
20150057920 | TRANSFER OF DATA FROM IMAGE-DATA-BASED MAP SERVICES INTO AN ASSISTANCE SYSTEM - A method for transferring data from an image-data-based map service for use in an assistance system of a vehicle includes the following: ascertaining the position and/or orientation of the vehicle, retrieving image data of the vehicle surroundings from the image-data-based map service, extracting items of information from the image data of the map service, and transferring the items of information into the assistance system. | 02-26-2015 |