A method for abrasion testing of a material sample includes abrading a surface of the sample with a tribometer, then characterizing particles in a portion of the flowing air that is received in an airborne particle collector. The testing may be done in an enclosure or container, such as an enclosure in or simulating a clean room environment. The drawing of air into the enclosure may be done by a fan pushing in air through a filter, such as a high efficiency particulate air (HEPA) filter. The enclosure may have vents (or louvers) through which some of the outflow of air may be directed, to help maintain an even flow, for example a laminar flow, of air through the container, and in particular past where the tribometer abrades the test material. The method may allow for real-time characterization of the particles produced by the testing.

An apparatus for performing a contact mechanics test in a substrate includes a stylus having at least two contact elements. Each contact element has a contact profile, and the contact elements are disposed in the stylus to define a stretch passage therebetween. The stylus is configured to deform the substrate so as to cause the substrate to flow between the contact elements and induce tension in the substrate in order to generate and preserve micromodifications in the substrate. Methods of performing a contact mechanics test using the apparatus are also provided.

The expandable jacket and flexible ring comprises of the segmented circular arch shaped plates and bands or rings around the segmented plates. The test preparation consists of a membrane surrounding a specimen with or without a filter, segmented plates surrounding the membrane, and bands or rings around the segmented plates to permit uniform radial expansion of the specimen through its height when increments of vertical load are applied during the test, thereby providing accurate values of area of cross-section, deviator stress, volume change, modulus of elasticity, Poisson's ratio and shear strength. Using the flexible ring, three-dimensional consolidation tests are performed to determine three-dimensional coefficient of consolidation and coefficients of consolidation in horizontal and vertical directions. Removable attachments are used for assembling the expandable jacket and flexible ring during the test. A calibration device is used to determine the modulus of elasticity of the membrane and expandable jacket and flexible ring.

A method for the handling of melt samples in a steelworks laboratory may involve processing and/or analyzing a melt sample in at least one first treatment apparatus and subsequently transporting the melt sample via at least one first transport path to at least one second treatment apparatus where the melt sample is subjected to further processing and/or analysis. As part of the transporting step, the method may involve clamping the melt sample on a sample carrier so that the sample carrier is transported together with the clamped-in melt sample between the treatment apparatuses and is positioned in the treatment apparatuses for processing and/or analysis.

A method for the handling of melt samples in a steelworks laboratory may involve processing and/or analyzing a melt sample in at least one first treatment apparatus and subsequently transporting the melt sample via at least one first transport path to at least one second treatment apparatus where the melt sample is subjected to further processing and/or analysis. As part of the transporting step, the method may involve clamping the melt sample on a sample carrier so that the sample carrier is transported together with the clamped-in melt sample between the treatment apparatuses and is positioned in the treatment apparatuses for processing and/or analysis.

An in vitro screening system includes a friction assembly including at least one motorized friction structural component configured to engage and remove material on a substrate and an analytics assembly including at least one sensor and circuitry configured to generate cleanser-specific material removal information responsive to a detected response associated with removal of a material on a substrate by the friction structural component.

An in vitro screening system includes a friction assembly including at least one motorized friction structural component configured to engage and remove material on a substrate and an analytics assembly including at least one sensor and circuitry configured to generate cleanser-specific material removal information responsive to a detected response associated with removal of a material on a substrate by the friction structural component.

The expandable jacket consists of the rubber membrane surrounding the cylindrical specimen, circular segmental metal plates surrounding the rubber membrane, and elastomeric rubber bands or rings around the segmental plates to permit uniform radial expansion and maintain uniform diameter of the specimen during the test and thereby providing accurate values of deviator stress, volume change characteristics and shear strength of soil specimen. To determine the three-dimensional coefficient of consolidation and coefficient of consolidation in horizontal direction, the flexible ring consists of all above structural components of expandable jacket except that a filter fabric or paper is wrapped around the cylindrical specimen, and then rubber membrane is mounted surrounding the filter paper or paper. The calibration device for calibration of the expandable jacket and flexible ring shall provide the magnitude of correction to be made in deviator stress and lateral resistance provided by the rubber bands or rings during the test.

Methods and systems of estimating a size of a chip in engine fluid of an engine are provided. One method comprises detecting the chip at a magnetic chip detector immersed in the engine fluid, burning the chip by Joule heating using a single delivery of electric current through the chip via the first and second terminals of the magnetic chip detector, determining an amount of energy consumed to burn the chip, and estimating the size of the chip based on the amount of energy consumed to burn the chip.

Determining a barrier effect of a coating for a medium includes: providing a substrate having the coating on its surface, the substrate undergoing a volume change on contact with the medium; conditioning the substrate with the coating; removing the coating from a first part of the surface, leaving the coating on a second part, the first part having an extent in a first direction delimited by the coating remaining on the second; determining a height profile of the coating on the second part and the first part on a path in the first direction; exposing the remaining coating and the first part to the medium; determining a second height profile of the coating on the second part and the first part on the path in the first direction and/or determining a difference in height profile on the second and first part with respect to the height profile determined beforehand.