A measuring system comprises a stand having a base plate and a vertical column fastened thereto, a stand carriage that is movable along the vertical column and having a counter bearing for placing the object, a runner that is fastened to the stand carriage and is movable relative thereto in a guided manner and has an indenter for penetrating the object, having at least one force generation actuator, at least one motion generation actuator, wherein the indenter is coupled to the stand carriage via the actuators. The measuring system further comprises a metrology frame which is fastened to the counter bearing and is supported laterally on the vertical column, a displacement measuring unit for measuring a displacement of the stand carriage and/or the runner with the indenter. The measuring system comprises a force measuring circuit and a displacement measuring circuit both being are largely configured separately from one another.

A measuring system comprises a stand having a base plate and a vertical column fastened thereto, a stand carriage that is movable along the vertical column and having a counter bearing for placing the object, a runner that is fastened to the stand carriage and is movable relative thereto in a guided manner and has an indenter for penetrating the object, having at least one force generation actuator, at least one motion generation actuator, wherein the indenter is coupled to the stand carriage via the actuators. The measuring system further comprises a metrology frame which is fastened to the counter bearing and is supported laterally on the vertical column, a displacement measuring unit for measuring a displacement of the stand carriage and/or the runner with the indenter. The measuring system comprises a force measuring circuit and a displacement measuring circuit both being are largely configured separately from one another.

The present disclosure describes systems and methods to compensate for error in a video extensometer system, including noise, perspective variations, and/or component placement and/or operation.

The present disclosure describes systems and methods to compensate for error in a video extensometer system, including noise, perspective variations, and/or component placement and/or operation.

A split-type device for measuring rock mass deformation under high hydraulic pressure and a construction method and use thereof. Main components of the device include a metal measuring rod, a magnetic iron core, a shell, a waterproof coil framework, a coil, a tail accessory, a cable clamp, a cable, a signal processing bin, etc. Main electronic components are treated by adopting the all-metal shell and a vacuum particle sealing double-layer sealing process, and have hydraulic pressure resistance of 5 MPa or above. Measurement signals feature centralized processing, digitization and dual utilization of signals, i.e., after data of a plurality of sensors is processed in an electronic bin and then digitized signals are connected to an independent reader outside the bin or a centralized acquisition device for in-situ tests.

A split-type device for measuring rock mass deformation under high hydraulic pressure and a construction method and use thereof. Main components of the device include a metal measuring rod, a magnetic iron core, a shell, a waterproof coil framework, a coil, a tail accessory, a cable clamp, a cable, a signal processing bin, etc. Main electronic components are treated by adopting the all-metal shell and a vacuum particle sealing double-layer sealing process, and have hydraulic pressure resistance of 5 MPa or above. Measurement signals feature centralized processing, digitization and dual utilization of signals, i.e., after data of a plurality of sensors is processed in an electronic bin and then digitized signals are connected to an independent reader outside the bin or a centralized acquisition device for in-situ tests.

The present invention discloses a double cantilever beam-encoding lead screw combined sensing tensile test method and machine. The double cantilever beam-encoding lead screw combined sensing tensile test machine comprises a main frame, a standard, a test piece and a microcomputer numerical control unit. The main frame is a force-deformation combined sensing mechanism composed of a double cantilever beam sensor, an encoding lead screw and a drive device. The double cantilever beam sensor is composed of a fixed cantilever beam sensor and a movable cantilever beam sensor. The encoding lead screw is composed of a drive lead screw and a tristate encoder. The double cantilever beam sensor matches with the encoding lead screw to achieve three functions, namely, test piece clamping, force sensing and deformation sensing, as well as to measure the size of the test piece.

The present invention discloses a double cantilever beam-encoding lead screw combined sensing tensile test method and machine. The double cantilever beam-encoding lead screw combined sensing tensile test machine comprises a main frame, a standard, a test piece and a microcomputer numerical control unit. The main frame is a force-deformation combined sensing mechanism composed of a double cantilever beam sensor, an encoding lead screw and a drive device. The double cantilever beam sensor is composed of a fixed cantilever beam sensor and a movable cantilever beam sensor. The encoding lead screw is composed of a drive lead screw and a tristate encoder. The double cantilever beam sensor matches with the encoding lead screw to achieve three functions, namely, test piece clamping, force sensing and deformation sensing, as well as to measure the size of the test piece.

An electromagnetic multiaxial fatigue testing machine includes a test piece fixing platform and an electromagnet loading mechanism arranged on a frame, wherein the electromagnet loading mechanism includes a first loading device for bend loading, and a second loading device for axial and torsional loading. The first loading device includes a first permanent magnet and a first electromagnet with a direction of a magnetic force generated therebetween is orthogonal to an axial direction of a test piece; the second loading device includes a second permanent magnet and a second electromagnet mounted on a swinging pair with a direction of a magnetic force generated therebetween is parallel to the axial direction of the test piece.

Disclosed are a projectile and a method of its manufacture for the field of investigating the strength properties of a solid material by application of a mechanical force and more particularly for bird strike tests consisting of a gel including glycerol. A projectile 1 according to the invention may have a central portion 4 of cylindrical shape including a substantially hemispherical portion 2, 3 at each of the ends thereof.