Abstract: A drag block for retaining slips on a tool includes a body having a substantially annular outer surface and a substantially annular inner surface, and a plurality of drag block members resiliently mounted to the substantially annular outer surface. Each of the plurality of drag block members includes a support element and a block element. The support element has a first end fixedly mounted to the substantially annular outer surface and a second, cantilevered end. The drag block is mounted to the second cantilevered end.

Abstract: A drag block for retaining slips on a tool includes a body having a substantially annular outer surface and a substantially annular inner surface, and a plurality of drag block members resiliently mounted to the substantially annular outer surface. Each of the plurality of drag block members includes a support element and a block element. The support element has a first end fixedly mounted to the substantially annular outer surface and a second, cantilevered end. The drag block is mounted to the second cantilevered end.

Abstract: An anti-extrusion ring including a ring body having a cross sectional shape, a radial contact surface making up a part of the cross sectional shape of the ring body the radial contact surface being configured to preferentially load a radial edge portion of the radial contact surface when the anti-extrusion ring is loaded, an axial contact surface making up a part of the cross sectional shape, the axial contact surface being configured to preferentially load an axial edge portion of the axial contact surface when the anti-extrusion ring is loaded, and an element load surface positioned between the radial edge portion and the axial edge portion and method for creating a seal.

Abstract: An anti-extrusion ring including a ring body having a cross sectional shape, a radial contact surface making up a part of the cross sectional shape of the ring body the radial contact surface being configured to preferentially load a radial edge portion of the radial contact surface when the anti-extrusion ring is loaded, an axial contact surface making up a part of the cross sectional shape, the axial contact surface being configured to preferentially load an axial edge portion of the axial contact surface when the anti-extrusion ring is loaded, and an element load surface positioned between the radial edge portion and the axial edge portion and method for creating a seal.

Abstract: An environmental conditioning assembly for use in mechanical testing at scales of microns or less. The assembly includes an enclosure housing with an environmental cavity therein. A sample stage is positioned within the environmental cavity and includes an option sample heater. The enclosure housing includes a cavity perimeter clustered around the sample stage, and the enclosure housing isolates the environmental cavity and the sample stage from an environment exterior to the enclosure housing. In an example, an expansion and contraction linkage maintains a sample on the sample stage at a static elevation according to heating or cooling fluctuations within the environmental cavity. A testing instrument access port extends through the enclosure housing into the environmental cavity.

Abstract: A method of calibrating a mechanical instrument assembly includes reading a memory device coupled with a mechanical testing instrument, the mechanical testing instrument having one or more mechanical characteristics with values unique to the mechanical testing instrument, and reading includes reading of one or more calibration values based on the one or more mechanical characteristic values. The method further includes calibrating the mechanical instrument assembly according to the one or more calibration values. The mechanical testing instrument is coupled with the mechanical instrument assembly.

Abstract: An environmental conditioning assembly for use in mechanical testing at scales of microns or less. The assembly includes an enclosure housing with an environmental cavity therein. A sample stage is positioned within the environmental cavity and includes an option sample heater. The enclosure housing includes a cavity perimeter clustered around the sample stage, and the enclosure housing isolates the environmental cavity and the sample stage from an environment exterior to the enclosure housing. In an example, an expansion and contraction linkage maintains a sample on the sample stage at a static elevation according to heating or cooling fluctuations within the environmental cavity. A testing instrument access port extends through the enclosure housing into the environmental cavity.

Abstract: An automated testing system includes systems and methods to facilitate inline production testing of samples at a micro (multiple microns) or less scale with a mechanical testing instrument. In an example, the system includes a probe changing assembly for coupling and decoupling a probe of the instrument. The probe changing assembly includes a probe change unit configured to grasp one of a plurality of probes in a probe magazine and couple one of the probes with an instrument probe receptacle. An actuator is coupled with the probe change unit, and the actuator is configured to move and align the probe change unit with the probe magazine and the instrument probe receptacle. In another example, the automated testing system includes a multiple degree of freedom stage for aligning a sample testing location with the instrument. The stage includes a sample stage and a stage actuator assembly including translational and rotational actuators.

Abstract: An automated testing system includes systems and methods to facilitate inline production testing of samples at a micro (multiple microns) or less scale with a mechanical testing instrument. In an example, the system includes a probe changing assembly for coupling and decoupling a probe of the instrument. The probe changing assembly includes a probe change unit configured to grasp one of a plurality of probes in a probe magazine and couple one of the probes with an instrument probe receptacle. An actuator is coupled with the probe change unit, and the actuator is configured to move and align the probe change unit with the probe magazine and the instrument probe receptacle. In another example, the automated testing system includes a multiple degree of freedom stage for aligning a sample testing location with the instrument. The stage includes a sample stage and a stage actuator assembly including translational and rotational actuators.

Abstract: An automated testing system includes systems and methods to facilitate inline production testing of samples at a micro (multiple microns) or less scale with a mechanical testing instrument. In an example, the system includes a probe changing assembly for coupling and decoupling a probe of the instrument. The probe changing assembly includes a probe change unit configured to grasp one of a plurality of probes in a probe magazine and couple one of the probes with an instrument probe receptacle. An actuator is coupled with the probe change unit, and the actuator is configured to move and align the probe change unit with the probe magazine and the instrument probe receptacle. In another example, the automated testing system includes a multiple degree of freedom stage for aligning a sample testing location with the instrument. The stage includes a sample stage and a stage actuator assembly including translational and rotational actuators.

Abstract: An automated testing system includes systems and methods to facilitate inline production testing of samples at a micro (multiple microns) or less scale with a mechanical testing instrument. In an example, the system includes a probe changing assembly for coupling and decoupling a probe of the instrument. The probe changing assembly includes a probe change unit configured to grasp one of a plurality of probes in a probe magazine and couple one of the probes with an instrument probe receptacle. An actuator is coupled with the probe change unit, and the actuator is configured to move and align the probe change unit with the probe magazine and the instrument probe receptacle. In another example, the automated testing system includes a multiple degree of freedom stage for aligning a sample testing location with the instrument. The stage includes a sample stage and a stage actuator assembly including translational and rotational actuators.

Abstract: An indentation assembly for sub-micron testing includes an indentation tip and a tip holder coupled with the indentation tip. The tip holder includes a first thermal conductivity and a first coefficient of thermal expansion. A tip holder mount configured for coupling with a transducer and the tip holder, the tip holder mount having a second thermal conductivity greater than the first thermal conductivity, and the tip holder mount has a second coefficient of thermal expansion greater than the first coefficient of thermal expansion. The tip holder mount has a mount length, and the tip holder further has a tip holder length greater that the mount length. The tip holder remotely positions the tip holder mount relative to the indentation tip. The tip holder length, volume and the first thermal conductivity cooperate to throttle heat transfer through the tip holder prior to reaching the tip holder mount.

Abstract: A method of calibrating a mechanical instrument assembly includes reading a memory device coupled with a mechanical testing instrument, the mechanical testing instrument having one or more mechanical characteristics with values unique to the mechanical testing instrument, and reading includes reading of one or more calibration values based on the one or more mechanical characteristic values. The method further includes calibrating the mechanical instrument assembly according to the one or more calibration values. The mechanical testing instrument is coupled with the mechanical instrument assembly.

Abstract: An automated testing system includes systems and methods to facilitate inline production testing of samples at a micro (multiple microns) or less scale with a mechanical testing instrument. In an example, the system includes a probe changing assembly for coupling and decoupling a probe of the instrument. The probe changing assembly includes a probe change unit configured to grasp one of a plurality of probes in a probe magazine and couple one of the probes with an instrument probe receptacle. An actuator is coupled with the probe change unit, and the actuator is configured to move and align the probe change unit with the probe magazine and the instrument probe receptacle. In another example, the automated testing system includes a multiple degree of freedom stage for aligning a sample testing location with the instrument. The stage includes a sample stage and a stage actuator assembly including translational and rotational actuators.

Abstract: An automated testing system includes systems and methods to facilitate inline production testing of samples at a micro (multiple microns) or less scale with a mechanical testing instrument. In an example, the system includes a probe changing assembly for coupling and decoupling a probe of the instrument. The probe changing assembly includes a probe change unit configured to grasp one of a plurality of probes in a probe magazine and couple one of the probes with an instrument probe receptacle. An actuator is coupled with the probe change unit, and the actuator is configured to move and align the probe change unit with the probe magazine and the instrument probe receptacle. In another example, the automated testing system includes a multiple degree of freedom stage for aligning a sample testing location with the instrument. The stage includes a sample stage and a stage actuator assembly including translational and rotational actuators.

Abstract: An indentation assembly for sub-micron testing includes an indentation tip and a tip holder coupled with the indentation tip. The tip holder includes a first thermal conductivity and a first coefficient of thermal expansion. A tip holder mount configured for coupling with a transducer and the tip holder, the tip holder mount having a second thermal conductivity greater than the first thermal conductivity, and the tip holder mount has a second coefficient of thermal expansion greater than the first coefficient of thermal expansion. The tip holder mount has a mount length, and the tip holder further has a tip holder length greater that the mount length. The tip holder remotely positions the tip holder mount relative to the indentation tip. The tip holder length, volume and the first thermal conductivity cooperate to throttle heat transfer through the tip holder prior to reaching the tip holder mount.