Method for determining the quality of non-crosslinked rubber mixtures, and corresponding device

What is claimed is: 1. A process for inline detection of particulate contaminants having a diameter >10 μm in a flow of uncrosslinked rubber mixture during processing of the rubber mixture in a rubber processing system, the process comprising: flowing uncrosslinked rubber mixture comprising rubber, filler, and cross-linking agent through a flow channel of the rubber processing system during processing of the rubber mixture, wherein the rubber mixture has a temperature >80° C.; projecting an ultrasound signal having a frequency of 0.5 MHz to 20 MHz through the uncrosslinked rubber mixture over a distance ≧10 mm at the temperature >80 ° C. during flow of the rubber mixture through the flow channel of the system; measuring at least one of: intensity of the ultrasound signal through the rubber mixture; and velocity of the ultrasound signal through the rubber mixture during flow of the rubber mixture through the flow channel of the processing system, wherein the ultrasound signal through the rubber mixture without particulate contaminants has first intensity and a first velocity, and the ultrasound signal through the rubber mixture with particulate contaminants has at least a second intensity and at least a second velocity; determining variations in the intensity and/or velocity of the ultrasound signal caused by a presence of particulate contaminants, wherein a pre-determined difference the first intensity and the second intensity and/or the first velocity and the second velocity provides an indication of the presence of particulate contaminants having a diameter >10 μm; and signaling detection of the particulate contaminants having a diameter >10 μm when the pre-determined difference in intensity and/or velocity provides an indication of the presence of particulate contaminants having a diameter >10 μm. 2. The process according to claim 1 , wherein measuring of a decrease in intensity indicates the presence of particulate contaminants. 3. The process according to claim 2 , wherein the velocity is indicative of particle size of the particulate contaminants, with larger particles having less slowing of the velocity, and wherein comparing of the measured velocities provides an indication of the presence of particulate contaminants having a diameter >10 μm as compared to particulates of smaller diameter. 4. The process according to claim 3 , wherein the flow channel comprises a detection band comprising at least one pair of ultrasound sensors spaced apart from one another by the ≧10 mm distance, wherein one sensor of the pair comprises an ultrasonic transmitter for transmitting a signal through the rubber mixture, and the other sensor of the pair comprises an ultrasonic receiver for detecting the ultrasonic signal upon passage through the rubber mixture, and the method further comprises passing the uncrosslinked rubber mixture through detection band. 5. The process according to claim 4 , wherein the detection band is composed of at least 2 of the sensor pairs arranged adjacent one another. 6. The process according to claim 5 , wherein: the uncrosslinked rubber mixture is flowing past the sensors in a stream having a width and the detection band is composed of an array of the sensor pairs arranged adjacent one another across the entire width of the uncrosslinked rubber mixture; and the method further comprises ultrasonically scanning an entire cross-section of the uncrosslinked rubber mixture as the rubber mixture passes through the detection band. 7. The process according to claim 6 , wherein the process further comprises, upon detection of particulate contaminants having a diameter >10 μm, removing the portion of the flow of the rubber mixture containing the contaminants from the flow channel. 8. The process according to claim 7 , wherein: the system comprises an extruder and the projecting and measuring occur along a portion of the extruder; the portion of the flow containing the contaminants is removed upon exiting of the extruder; the frequency is 2 MHz to 10 MHz; the distance is ≧20 mm; and the particulate contaminants have a diameter >100 μm with a melting temperature greater than the temperature of the uncrosslinked rubber mixture when the ultrasonic measurement is being made. 9. The process according to claim 8 , wherein: the temperature is greater than 100° C.; the frequency is 4 MHz to 7 MHz; the distance is ≧30 mm; and the particulate contaminants have a diameter >500 μm. 10. An apparatus for processing an uncrosslinked rubber mixture and detecting particulate contaminants having a diameter greater than 10 μm in the uncrosslinked rubber mixture during processing thereof, the apparatus comprising: an extruder; at least one detection band disposed along the extruder, wherein the detection band comprises at least 2 ultrasound sensor pairs arranged alongside one another wherein sensors of each sensor pair are spaced apart from one another by ≧10 mm, and one sensor of each pair comprises an ultrasonic transmitter for sending an ultrasonic signal of 0.5 MHz to 20 MHz through the rubber mixture, and the other sensor of each pair comprises an ultrasonic receiver for detecting at least one of: intensity of the ultrasonic signal upon passage through the rubber mixture; and velocity of the ultrasonic signal upon passage through the rubber mixture; and at least one processing unit for conducting and evaluating the process as claimed in any of claim 1 , 2 , 3 or 6 . 11. A process for the detection of particulate contaminants having a diameter >10 μm in a flow of uncrosslinked rubber mixture during processing of the rubber mixture in a processing system, the process comprising: projecting an ultrasound signal having a frequency of 0.5 MHz to 20 MHz through the uncrosslinked rubber mixture over a path length (s) during flow of the rubber mixture through the processing system; measuring intensity of the ultrasound signal through the rubber mixture during flow of the rubber mixture through the processing system, wherein the ultrasound signal through the rubber mixture without particulate contaminants has at least a first intensity (I average ), and the ultrasound signal through the rubber mixture with particulate contaminants at a time (t) has at least a second intensity (I); calculating a relative attenuation coefficient α rel. at a processing time (t), wherein: α rel. ( t )=− In ( I ( t )/ I average )/ s  wherein a predetermined increase in α rel. is indicative of presence of contaminants having a diameter >10 μm; and determining the presence of contaminants when α rel. is greater than a predetermined value.