A system for causing wear to a material in representative downhole conditions is provided, and can include a housing with a chamber at least partially filled with a fluid, an abrasion device at least partially immersed in the fluid, a heat transfer element thermally coupled to a housing, an engagement arm coupled to the housing and a test sample attached to the engagement arm that can apply an engagement force to the test sample causing engagement of the test sample with the abrasion device. An actuation device can displace the abrasion device relative to the test sample, and cause wear of the test sample during a wear test in response to the engagement of the test sample with the abrasion device. A controller can control a thermal output of the heat transfer element to maintain the chamber within a temperature range that is representative of the downhole conditions.

A method of measuring cement volumetric changes includes loading a sample cement into a flexible container and surrounding the flexible container by a column of fluid in a chamber. The temperature of the column of fluid is adjusted to a cement setting temperature, and the sample cement is allowed to set over several hours. The pressure of the column of fluid is adjusted to a test pressure. The temperature of the column of fluid in the chamber is adjusted to induce volumetric changes in the set cement. As the volume of the set cement changes, fluid volume adjustments are applied to the column of fluid in the chamber to maintain the pressure of the column of fluid in the chamber constant at the test pressure. The volumetric changes in the set cement are determined from the fluid volume adjustments applied to the column of fluid in the chamber.

Disclosed is a device for analyzing dynamic characteristics of a carbon composite material based on a test temperature, an orientation of a carbon material, and an external loading pattern applied thereto. The device includes a sensitivity analyzer configured to calculate a frequency response function of the carbon composite material based on a physical force signal and a vibration signal; and calculate a sensitivity of the carbon composite material to each of variations in the test temperature, an orientation of a carbon material contained in the carbon composite material, and the external loading pattern applied thereto, based on the calculated frequency response function.

A system for causing wear to a material in representative downhole conditions is provided, and can include a housing with a chamber at least partially filled with a fluid, an abrasion device at least partially immersed in the fluid, a heat transfer element thermally coupled to a housing, an engagement arm coupled to the housing and a test sample attached to the engagement arm that can apply an engagement force to the test sample causing engagement of the test sample with the abrasion device. An actuation device can displace the abrasion device relative to the test sample, and cause wear of the test sample during a wear test in response to the engagement of the test sample with the abrasion device. A controller can control a thermal output of the heat transfer element to maintain the chamber within a temperature range that is representative of the downhole conditions.

An apparatus for testing paving samples includes a base that includes a paving sample tray about the cabinet and configured for translation relative to the cabinet. A roller is configured for imparting compressive forces to a sample carried by the sample tray. An arm is configured for moving the roller from a stowed position to an in-use position where the roller contacts the sample. A cylinder assembly having a piston therein supplies pressure forces to the arm to move the arm from the stowed position to the in-use position, wherein a depth of travel of the arm is limited by the sample. As the sample is compressed, the depth of travel increases. A measurement device is in communication with the cylinder for determining an amount of travel of the arm to thus determine an amount of compression of the sample.

Disclosed herein are devices and methods for generating and/or verifying a predictive temperature stress and time creep modulus, approving or rejecting a medical device, verifying a medical device design using a linear device model, and generating coefficients using thermal analysis.

A fatigue limit stress specification system includes: a vibration generator that repeatedly applies a load to an object to be measured; a temperature sensor that measures a change in temperature of the object to be measured; and an information processing device that measures a fatigue limit stress of the object to be measured. The information processing device obtains a relation between a temperature amplitude of a fundamental frequency component of vibration for the object to be measured and a temperature amplitude of a second harmonic component of the vibration, performs fitting on the relation by using a first approximate line and a second approximate line, the first approximate line including a quadratic curve, the second approximate line including a quadratic curve, and obtains the fatigue limit stress of the object to be measured based on an intersection of the first approximate line and the second approximate line.

Disclosed is a device for analyzing dynamic characteristics of a carbon composite material based on a test temperature, an orientation of a carbon material, and an external loading pattern applied thereto. The device includes a sensitivity analyzer configured to calculate a frequency response function of the carbon composite material based on a physical force signal and a vibration signal; and calculate a sensitivity of the carbon composite material to each of variations in the test temperature, an orientation of a carbon material contained in the carbon composite material, and the external loading pattern applied thereto, based on the calculated frequency response function.

An adjustable induction heating coil and cooling plenum assembly for use in a strain-controlled thermo-mechanical fatigue test of a specimen, wherein the specimen is suspended in a load frame under a constant tensile force, comprising: a heating coil comprised of a plurality of windings of a metal tube having a first end and a second end, comprised of metallic tubing suitable for connection to a radio frequency induction furnace; a moveable stage slideably connected to a stage assembly comprising: a dielectric block having at least one elongated slot; a connection block slideably connected to the dielectric, having a hollow conduit through the heating coil connection block and a connection fitting fixedly attached at first and second ends of the hollow conduit; and a cooling plenum assembly comprising: a relatively thin, flat toroid-like shaped plenum having a cap fixedly connected to a body, a hollow central bore, and a perimeter sidewall surrounding the hollow central bore; a first perimeter shape of the hollow central bore substantially conforms to a second perimeter shape of the specimen; a continuous hollow channel within said perimeter sidewall; a continuous opening of between 0.002 and 0.004 inches between the cap and the body on an interior side of said perimeter sidewall.

The invention pertains to performing bonding strength testing between a test material and a container. A sample preparation device to make a test sample was disclosed. This device included a container with an insert on each end. The inserts have a portion that protrudes into the container. When test material is added to the sample preparation device, a groove was formed in test sample. These grooves reduce the amount of boundary effects that are present during testing.

A system and method for performing bond strength testing was also disclosed. In this system, a test sample was formed using the sample preparation device. This is placed upon a support and a half-spherical force applier is placed on top of the test sample. A press is used to apply force to the force applier and indirectly to the test sample.