Hardness testers having a pivoting body and capable of providing power to accessories on the pivoting body are disclosed. An example hardness testing device includes: a rotating carriage configured to: hold at least one of an indenter or an objective and at least one accessory; and rotate to selectively place the at least one indenter or objective or the at least one accessory in an operative position to operate the at least one indenter or objective or the at least one accessory; a carriage mount configured to support the rotating carriage; and an electrical contact block mounted stationary with respect to the carriage mount, the electrical contact block comprising a plurality of electrical contacts configured to make electrical contact with a counterpart electrical contact block of the at least one accessory coupled to the rotating carriage when the at least one accessory is positioned in the operative position.

This disclosure relates generally to enabling a user to (1) determine the radial stiffness of the outer surface of a winding or wound roll, and (2) when coupled with a winding/contact model results in a virtual instrument allowing the user to explore the residual stresses due to winding in roll-to-roll manufacturing process machines, and (3) allows the user to predict winding defects and hence roll quality based upon the known residual stresses. Wound roll models require the input of a radial modulus of elasticity which is state dependent on interlayer pressure. The hardware of the disclosure can be used to determine this radial modulus and serves to enable the user to (1) use winding/contact models and (2) with measurements made during or after winding enable the user to estimate the winding residual stresses.

An indenter is made of polycrystalline diamond and has a tip having a spherical surface with a radius of 10 to 2000 m.

A rock sample is nano-indented from a surface of the rock sample to a specified depth less than a thickness of the rock sample. While nano-indenting, multiple depths from the surface to the specified depth and multiple loads applied to the sample are measured. From the multiple loads and the multiple depths, a change in load over a specified depth is determined, using which an energy associated with nano-indenting rock sample is determined. From a Scanning Electron Microscope (SEM) image of the nano-indented rock sample, an indentation volume is determined responsive to nano-indenting, and, using the volume, an energy density is determined. It is determined that the energy density associated with the rock sample is substantially equal to energy density of a portion of a subterranean zone in a hydrocarbon reservoir. In response, the physical properties of the rock sample are assigned to the portion of the subterranean zone.

A method for testing an interfacial tribochemical reaction between a diamond wafer and active metal abrasive or metal oxide abrasive is provided. A surface of a diamond indenter used in a nano scratch tester is coated with a layer of the active metal abrasive or the metal oxide abrasive with uniform and controllable thickness by magnetron sputtering, and an interface interaction between the layer of the active metal abrasive or the metal oxide abrasive and the diamond wafer is controlled by a scratch test of the diamond wafer. Chemical components of an interaction section on a surface of the diamond wafer are analyzed by the scanning probe micro Raman spectrometer.

An indentation type hardness tester applies a predetermined force to an indenter and the indenter produces an indentation on a test specimen, and then measures the shape and size of the indentation. The hardness tester has a tester body and different frames. The tester body has a cavity and a magnetic base. The user selects different frames based on measurement needs and installs the frame into the magnetic base of the tester body. The testing head is equipped with an optical imaging system, the front end of the testing head is equipped with a removable load cell, and the front end of the load cell is equipped with an indenter. The indenter, load cell and optical system are coaxially oriented. A motor moves the tester body to perform the indentation.

A sample gripping and heating assembly includes an assembly housing and first and second heating grips coupled with the assembly housing. The first and second heating grips each include a gripping surface, and the gripping surfaces of the first and second heating grips are opposed to each other. Each of the first and second heating grips further includes a heating element adjacent to the gripping surface. Optionally, the sample gripping and heating assembly is included in a heating system including a probe heater having a probe heating element for heating of a probe. The heating system is included with a testing assembly having a stage coupled with the sample gripping and heating assembly, and a transducer assembly coupled with the probe heater.

The present disclosure relates to bendable and/or foldable articles and uses thereof and to a method of providing bendable and/or foldable articles. The articles are of translucent and brittle material, such as glass, glass ceramic, ceramic or crystals. The articles may be used as a display cover such as a protecting cover in displays in, for example, smartphones, tablet computers, or TV devices. The articles may also be used as a substrate for electronic components, such as OLEDs or LEDs.

A measuring system for detecting measuring signals during a penetration movement of a penetration body into a surface of a test body, in particular for determining the scratch resistance of the surface of the test body, or during a scanning movement of the penetration body on the surface of the test body, in particular for determining the surface roughness, including a housing with a power generating device, which is operatively connected to a penetration body for generating a displacement movement of the penetration body along a longitudinal axis of the housing, and which actuates a penetration movement of the penetration body into the surface of the test body to be examined, or which positions the penetration body on the surface of the test body for scanning, and having at least one first measuring device for measuring the penetration depth into the surface of the test body or a displacement movement of the penetration body along the longitudinal axis of the housing during a scanning movement on the surface of the test body. The power generating device is actuated by a pressure medium for the penetration movement of the penetration body.

A heated or cooled sample holding stage for use in a nanoindentation measurement system is described. The geometry of the design and the selection of materials minimizes movement of a sample holder with respect to a nanoindentation tip over a wide range of temperatures. The system controls and minimizes motion of the sample holder due to the heating or cooling of the tip holder and/or the sample holder in a high temperature nanoindentation system. This is achieved by a combination of geometry, material selection and multiple sources and sinks of heat. The system is designed to control both the steady state and the transient displacement response.