Abstract: A process is provided for imaging a surface of a specimen with an imaging system that employs a BD objective having a darkfield channel and a bright field channel, the BD objective having a circumference. The specimen is obliquely illuminated through the darkfield channel with a first arced illuminating light that obliquely illuminates the specimen through a first arc of the circumference. The first arced illuminating light reflecting off of the surface of the specimen is recorded as a first image of the specimen from the first arced illuminating light reflecting off the surface of the specimen, and a processor generates a 3D topography of the specimen by processing the first image through a topographical imaging technique. Imaging apparatus is also provided as are further process steps for other embodiments.

Abstract: A process is provided for imaging a surface of a specimen with an imaging system that employs a BD objective having a darkfield channel and a bright field channel, the BD objective having a circumference. The specimen is obliquely illuminated through the darkfield channel with a first arced illuminating light that obliquely illuminates the specimen through a first arc of the circumference. The first arced illuminating light reflecting off of the surface of the specimen is recorded as a first image of the specimen from the first arced illuminating light reflecting off the surface of the specimen, and a processor generates a 3D topography of the specimen by processing the first image through a topographical imaging technique. Imaging apparatus is also provided as are further process steps for other embodiments.

Abstract: A method for cutting compounded rubber for reflected light measurement of the disbursement of fillers therein is disclosed. The method includes subjecting a sample of compounded rubber to a dynamic pulling force, and cutting the sample while it is subjected to the dynamic pulling force. The method may further include the step of pressing the sample to remove entrapped air from the sample, and, preferably, the method includes cooling the sample during such a pressing step. Cutting the sample while it is subjected to a dynamic pulling force will reduce, and, preferably, eliminate, the presence of smears on a cut surface of the sample. By reducing the amount of entrapped air within a sample and, further, reducing the occurrence of smearing during cutting of the sample, a subsequent reflected light measurement of the dispersion of fillers within the compounded rubber sample is more accurate.

Abstract: An apparatus for testing polymeric samples is shown in which a polymer specimen is subjected to sinusoidal, oscillatory motion. The oscillatory motion is generated by the use of a continuously variable eccentric cam that is affixed to a drive shaft rotated by a motor. The amplitude of oscillation is determined by the eccentricity of the cam, and verified by measurement of angular deflection. The eccentricity of the cam can be altered, in one embodiment, through the manual manipulation of an adjustable nut, and, in another, automated embodiment, through the motion of the rotating motor. The eccentricity of the cam is continuously variable and can quickly be changed within a single test.

Abstract: A method for cutting compounded rubber for reflected light measurement of the disbursement of fillers therein is disclosed. The method includes subjecting a sample of compounded rubber to a dynamic pulling force, and cutting the sample while it is subjected to the dynamic pulling force. The method may further include the step of pressing the sample to remove entrapped air from the sample, and, preferably, the method includes cooling the sample during such a pressing step. Cutting the sample while it is subjected to a dynamic pulling force will reduce, and, preferably, eliminate, the presence of smears on a cut surface of the sample. By reducing the amount of entrapped air within a sample and, further, reducing the occurrence of smearing during cutting of the sample, a subsequent reflected light measurement of the dispersion of fillers within the compounded rubber sample is more accurate.