Test method for fracture toughness GIC based on ubiquitiform theory

A new fracture toughness test method for obtaining the crack initiation fracture toughness GIC and crack propagation fracture toughness GC was proposed. This method was based on the basic idea of ubiquitiform geometry and experimental results showing that material fracture surfaces possess ubiquitiform characteristics. A uniaxial tensile test was performed on plate specimens with cracks made by ductile cast iron to generate Mode I fracture failure. Loading-displacement curves were recorded in accordance with the experimental process, and the crack-initiation work W1 and the crack propagation work W2 were recorded. The morphology of the fracture surface was observed through electron microscopy, and the ubiquitiformal complexity D of the fracture surface was calculated on the basis of ubiquitiform theory. The ubiquitiform fracture area of the fracture surface was further obtained. The formula for ubiquitiform fracture energy was provided and used to calculate the ubiquitiform fracture energies Guf1 and Guf2 of the tested material. By analyzing the relationship between the above ubiquitiform fracture energy and fracture toughness GIC, a test method for determining fracture toughness based on ubiquitiform fracture energy was proposed. The experimental fracture toughness test results for several cracks of different sizes were consistent within a certain range of crack lengths.

Automated summary

A new test method for fracture toughness was proposed, which could obtain the crack initiation fracture toughness and crack propagation fracture toughness. The method was based on the idea of ubiquitiform geometry and the observation of ubiquitiform characteristics on fracture surfaces. Plate specimens with cracks made of ductile cast iron were subjected to a uniaxial tensile test to generate Mode I fracture failure. The loading-displacement curves were recorded, and the crack-initiation work and crack propagation work were measured. The morphology of the fracture surface was observed through electron microscopy, and the ubiquitiformal complexity was calculated. The formula for ubiquitiform fracture energy was provided, and the relationship between ubiquitiform fracture energy and fracture toughness was analyzed to propose a new test method. The experimental results showed consistent fracture toughness within a certain range of crack lengths.