A method of predicting joining strength of joined dissimilar materials, includes performing a joining strength test on a plurality of specimens of joined dissimilar materials each having different joining information, and acquiring force-displacement data on a basis of the joining information; constructing, in a prediction system, an artificial neural network model for predicting the force-displacement data and the joining strengths from the joining information; learning the artificial neural network model by inputting the force-displacement data to the prediction system, the force-displacement data obtained through the joining strength test; inputting joining information to be predicted to the prediction system by using a computer running a software for performing prediction for the joining strength and connected to a host computer of the prediction system through a network; and predicting, by the learned artificial neural network model, force-displacement value and joining strength.

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.

Disclosed is a method of predicting a lifespan of a material by using a material parameter and by using Equation described below.

[00001]$y=\gamma \times \exp \left[-{\left(\frac{x}{\theta }\right)}^{\beta }\right]$

in which y is the physical property retention rate, x is the aging time, θ is a scale parameter, β is a shape parameter, and γ is the material parameter.

Disclosed is a method of predicting a lifespan of a material by using a material parameter and by using Equation described below.

[00001]$y=\gamma \times \exp \left[-{\left(\frac{x}{\theta }\right)}^{\beta }\right]$

in which y is the physical property retention rate, x is the aging time, θ is a scale parameter, β is a shape parameter, and γ is the material parameter.

A test method for characterizing the mechanical properties including the surface adhesion energy γ on the basis of the experimentally derived P-A relationship, where P means the indentation load under the penetration depth h of an indenter pressed onto a test specimen with surface adhesion, and A means the contact area of indentation at the contact radius a under the applied load of P. This test method enables the implementation for quantitatively as well as simultaneously characterizing the adhesion energy as well as the various mechanical properties (elastic/elastoplastic/viscoelastic properties) of soft materials.

A test method for characterizing the mechanical properties including the surface adhesion energy γ on the basis of the experimentally derived P-A relationship, where P means the indentation load under the penetration depth h of an indenter pressed onto a test specimen with surface adhesion, and A means the contact area of indentation at the contact radius a under the applied load of P. This test method enables the implementation for quantitatively as well as simultaneously characterizing the adhesion energy as well as the various mechanical properties (elastic/elastoplastic/viscoelastic properties) of soft materials.

An example material testing system includes: a crosshead configured to be actuated to transfer testing force to a test specimen during a material test; an actuator configured to actuate the crosshead and to apply the testing force to the crosshead; a force sensor configured to measure force applied by the crosshead to the specimen; and a control processor configured to: determine a reference force range based on a first force measurement from the force sensor in response to initiation of movement of the crosshead; and in response to a second force measurement by the force sensor that is outside of the reference force range, controlling the actuator to apply a braking force to the crosshead.

An example material testing system includes: a crosshead configured to be actuated to transfer testing force to a test specimen during a material test; an actuator configured to actuate the crosshead and to apply the testing force to the crosshead; a force sensor configured to measure force applied by the crosshead to the specimen; and a control processor configured to: determine a reference force range based on a first force measurement from the force sensor in response to initiation of movement of the crosshead; and in response to a second force measurement by the force sensor that is outside of the reference force range, controlling the actuator to apply a braking force to the crosshead.

Disclosed is a testing device for measuring interfacial shear properties between fibers and media, including a main body, which is a rectangular plate-like structure with L-shaped plates provided at the bottom ends of the main body, a connecting rod provided at a top right of the main body, a groove provided at the top of the main body; and four rotating grooves are provided inside the groove. The rotating grooves are cylindrical structures with raised centers at both ends; and a mounting piece is installed above the left end of the main body; a magnet of a displacement micrometer is connected to a tension trolley, a high-definition camera is turned on, weights are added into a loading bucket and the fiber movement is observed until the fiber is pulled out or sliding friction occurs, and then the camera is stopped and accurate data is tested.