The invention discloses a method for obtaining the geometrical and mechanical parameters of rock samples and a holographic scanning system thereof, wherein the system includes an observation mechanism, a multi-scale penetration mechanism, a grinding mechanism, a rock sample installation mechanism arranged on a three-axis precision motion platform, and an industrial computer controlling the operation mode of each mechanism of the platform Indentation/rotary penetration test, pulse echo signal acquisition, three-dimensional surface topography reconstruction, layer by layer grinding and repeated experiments are carried out. The geometric parameters and corresponding mechanical field parameters are obtained by spatial interpolation of the three-dimensional parameter lattice accumulated by several layers of single-layer rock parameters. The holographic scanning system and method can obtain the real spatial distribution of various media in rock samples. Combined with high performance numerical calculation method, it provides a more scientific method for the analysis of rock mechanical properties, failure and instability.

The invention discloses a method for obtaining the geometrical and mechanical parameters of rock samples and a holographic scanning system thereof, wherein the system includes an observation mechanism, a multi-scale penetration mechanism, a grinding mechanism, a rock sample installation mechanism arranged on a three-axis precision motion platform, and an industrial computer controlling the operation mode of each mechanism of the platform Indentation/rotary penetration test, pulse echo signal acquisition, three-dimensional surface topography reconstruction, layer by layer grinding and repeated experiments are carried out. The geometric parameters and corresponding mechanical field parameters are obtained by spatial interpolation of the three-dimensional parameter lattice accumulated by several layers of single-layer rock parameters. The holographic scanning system and method can obtain the real spatial distribution of various media in rock samples. Combined with high performance numerical calculation method, it provides a more scientific method for the analysis of rock mechanical properties, failure and instability.

The invention relates to a measuring System, a measuring arrangement and a method for detecting measuring signals during a penetration movement of a penetration body (41) into a surface of a test body (14), in particular for hardness measurement or for determining the Scratch resistance of the surface of the test body (14), or for detecting measuring signals during a scanning movement of the penetration body (41) on the surface of the test body (14), in particular for determining the surface roughness, comprising a housing (47) provided with a power generating device (44) which is operatively connected to a penetration body (41) for generating a displacement movement of the penetration body (41) along a displacement axis (48) of the penetration body (41) and which actuates a penetration movement of the penetration body (41) into the surface to be examined of the test body (14), or which positions the penetration body (41) on the surface of the test body (14) for scanning, and further comprising at least one first measuring device (78) for measuring the penetration depth in the surface of the test body (14) or a displacement movement of the penetration body (41) along its displacement axis (48) during a scanning movement on the surface of the test body (14), wherein the power generating device (44) actuates the displacement movement of the penetration body (41) by means of a magnetic force.

The invention relates to a measuring System, a measuring arrangement and a method for detecting measuring signals during a penetration movement of a penetration body (41) into a surface of a test body (14), in particular for hardness measurement or for determining the Scratch resistance of the surface of the test body (14), or for detecting measuring signals during a scanning movement of the penetration body (41) on the surface of the test body (14), in particular for determining the surface roughness, comprising a housing (47) provided with a power generating device (44) which is operatively connected to a penetration body (41) for generating a displacement movement of the penetration body (41) along a displacement axis (48) of the penetration body (41) and which actuates a penetration movement of the penetration body (41) into the surface to be examined of the test body (14), or which positions the penetration body (41) on the surface of the test body (14) for scanning, and further comprising at least one first measuring device (78) for measuring the penetration depth in the surface of the test body (14) or a displacement movement of the penetration body (41) along its displacement axis (48) during a scanning movement on the surface of the test body (14), wherein the power generating device (44) actuates the displacement movement of the penetration body (41) by means of a magnetic force.

A two-dimensional nanoindentation measurement apparatus includes a first actuator that imparts a first force in a first direction, and a second actuator that imparts a second force in a second direction orthogonal to the first direction. A first elongate member has a first end attached to the first actuator and a second end attached to an indenter tip that engages the surface of the sample. A second elongate member includes a first end attached to the second actuator and a second end connected to the second end of the first elongate member. The first elongate member is rigid in the first direction and compliant in the second direction, and the second elongate member is rigid in the second direction and compliant in the first direction. The first force is imparted to the indenter tip in the first direction through the first elongate member, and the second force is imparted to the indenter tip in the second direction through the second elongate member.

A scratch tester has at least one cutter that moves simultaneously both rotationally and axially relative to the rock it is cutting. When rotational and axial movements are constant, the cutter generates a helical groove in the rock. In borehole embodiments, the scratch tester is fixed at a desired location using centralizers, and the cutter is provided on a motorized platform/track that translates between the centralizers and rotates around a central axis. The cutter faces outward and extends via a cutter arm to engage and carve a helical groove in the borehole wall. A laboratory scratch tester includes a holder for a solid cylindrical core sample and a motorized translating frame on which a cutter extends. The cutter is directed toward the core sample, and the holder with the core sample is rotated by a motor so that as the cutter translates relative thereto, a helical groove is cut thereinto.

A scratch tester has at least one cutter that moves simultaneously both rotationally and axially relative to the rock it is cutting. When rotational and axial movements are constant, the cutter generates a helical groove in the rock. In borehole embodiments, the scratch tester is fixed at a desired location using centralizers, and the cutter is provided on a motorized platform/track that translates between the centralizers and rotates around a central axis. The cutter faces outward and extends via a cutter arm to engage and carve a helical groove in the borehole wall. A laboratory scratch tester includes a holder for a solid cylindrical core sample and a motorized translating frame on which a cutter extends. The cutter is directed toward the core sample, and the holder with the core sample is rotated by a motor so that as the cutter translates relative thereto, a helical groove is cut thereinto.

A method for evaluating a weld in a formed object includes performing a contact mechanics test of a first region that includes the weld and storing one or more corresponding weld surface mechanical property measurements, performing a contact mechanics test of a second region that excludes the weld and storing one or more corresponding base material surface mechanical property measurements, determining a relative difference in the weld surface mechanical property measurements and the base material surface mechanical property measurements, determining one or more weld width measurements on the exterior surface of the formed object, and evaluating the weld based on the determined relative difference in the weld surface mechanical property measurements and the base material surface mechanical property measurements in relation to the determined weld width measurements in order to provide an index of weld quality that is traditionally measured through a destructive test or examination.

A method for evaluating a weld in a formed object includes performing a contact mechanics test of a first region that includes the weld and storing one or more corresponding weld surface mechanical property measurements, performing a contact mechanics test of a second region that excludes the weld and storing one or more corresponding base material surface mechanical property measurements, determining a relative difference in the weld surface mechanical property measurements and the base material surface mechanical property measurements, determining one or more weld width measurements on the exterior surface of the formed object, and evaluating the weld based on the determined relative difference in the weld surface mechanical property measurements and the base material surface mechanical property measurements in relation to the determined weld width measurements in order to provide an index of weld quality that is traditionally measured through a destructive test or examination.

A measuring system for detecting measuring signals during a penetration movement of a penetration body into a surface of a test body, 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.