Systems and methods for determining mechanical properties of formation rock using, for example, millimeter-scale test samples of the formation rock are disclosed. The test samples may be single edge notched beam (SENB) test samples. The systems and methods may include performing laboratory testing on the SENB test samples and recording laboratory testing data obtained from the laboratory testing and performing a simulation on a numerical model of the SENB test samples and recording the simulation data obtained from the simulation. The laboratory testing data and the simulation data may be compared, and a determination may be made as to whether a selected degree of correlation is present between the laboratory testing data and the simulation exists. Mechanical properties of the formation rock are obtained from the simulation data when the selected degree of correlation exists between the laboratory testing data and the simulation data.

For providing a method capable of physically and objectively evaluating the consistency and state of a stool, provided is a method for measuring a stool consistency with a texture analyzer provided with a probe, the probe having a shape capable of measuring a consistency of a stool in a liquid form and in a solid form.

For providing a method capable of physically and objectively evaluating the consistency and state of a stool, provided is a method for measuring a stool consistency with a texture analyzer provided with a probe, the probe having a shape capable of measuring a consistency of a stool in a liquid form and in a solid form.

The present technology provides an impact test device and method. The rotational speed of a rotary drum with a rubber sample attached on the outer surface is set to a desired rotational speed, the impact cycle for the surface of the rubber sample of the contact member by the repeat-impact mechanism is set to a desired cycle, the impact load by the contact member is set to a desired impact load by a weight member, a desired contact member is selected from among the plurality of contact members with different specifications, and the contact member is repeatedly made to collide with the surface of the rubber sample by rotating a vertical excitation roller and pivoting the arm portion in the vertical direction with a rotation shaft.

A device is configured to allow for the load-bearing capacity of cylindrical shells of a composite fiber material that are at risk of buckling to be determined. The device allows for deriving improved reduction factors for analytical calculation of the design load, which enables an improved approximation to the actual load-bearing capacity. The device includes a load distribution head for applying an axially acting force to a cylinder shell introduced into the device; a dent actuator for producing a single dent in a surface of the cylinder shell in a predetermined dent direction with a predetermined dent depth; a fixed support for fixing the dent depth of the single dent produced by the dent actuator in the predetermined dent direction; a dent force sensor for determining a dent force in the predetermined dent direction of the single dent that is fixed in the predetermined dent direction when a steadily increasing, axially acting force is applied to the cylinder shell by the load distribution head; a control unit for actuating the load distribution head for applying a steadily increasing, axially acting force to the cylinder shell until a complete failure of the cylinder shell is detected as a load step by an axial force sensor; and a digital data memory for storing a current dent force in an event of a complete failure of the cylinder shell and the applied axially acting force on the cylinder shell at the current dent force for the predetermined dent depth.

Embodiments of the present application provide a method for preparing a sample for wafer level failure analysis. The method includes that: a plurality of splitting points are formed on a surface of a selected region of a to-be-analyzed sample along a preset direction, the plurality of splitting points being arranged in a straight line; and the to-be-analyzed sample is split by taking the straight line where the plurality of splitting points are located as a splitting line, to expose a cross section of a side surface of the to-be-analyzed sample and form the sample for the wafer level failure analysis.

Embodiments of the present application provide a method for preparing a sample for wafer level failure analysis. The method includes that: a plurality of splitting points are formed on a surface of a selected region of a to-be-analyzed sample along a preset direction, the plurality of splitting points being arranged in a straight line; and the to-be-analyzed sample is split by taking the straight line where the plurality of splitting points are located as a splitting line, to expose a cross section of a side surface of the to-be-analyzed sample and form the sample for the wafer level failure analysis.

A multimode ultrasonic probe tip and transducer integrated into a micro tool, such as a nano indenter or a nano indenter interfaced with a Scanning Probe Microscope (SPM) is described. The tip component may be utilized to determine mechanical properties or characteristics of a sample, including for example, complex elastic modulus, hardness, friction coefficient, and strain and stress at nanometer scales and high frequencies. The tip component is configured to operate at multi-resonant frequencies providing sub-nanometer vertical resolution. The tip component may be quasi-statistically calibrated and contact mechanics constitutive equations may be utilized to derive mechanical properties of a sample. Contact mechanical impedance and acoustic impedance may also be compared.

A seat foam inspection gage including a foam displacement indicator is used for inspecting seat foam on site at a manufacturing plant. The seat foam inspection gage includes a cylindrical body and a ball arranged within the body. The seat foam inspection gage also includes an indicator arranged on a top surface of the body, wherein the indicator measures distance of a foam displacement of the seat foam at a seat manufacturing facility. The seat foam inspection gage may take the distance of foam displacement and convert that number into an IFD number, thus allowing for quick comparison of seat foam hardness across an entire seating surface and across all seats being manufactured in a facility without having to send the seat foam to an offsite quality control lab to measure the IFD with large frame machinery.

An estimation apparatus includes: an acquisition section that acquires a measurement result of a measurement unit that measures an object to be an estimation target of a contact sense in a contactless manner; a determination section that makes a determination as to an aspect of the object or a measurement condition of the object on a basis of the measurement result of the measurement unit; a selection section that selects, on a basis of a result of the determination, an estimation scheme to be used for estimation of the contact sense of the object from among a plurality of estimation schemes; and an estimation section that estimates the contact sense of the object using the selected estimation scheme.