Coronary artery stenosis is a disease caused by arteriosclerosis. In clinical practice, interventional surgery is performed according to the degree of vascular stenosis. However, most of the current diagnosis is based on angiographic appearance. Due to the lack of physiological and functional information, it is difficult to make an accurate assessment. Fractional flow reserve (FFR) is the gold standard for the diagnosis of myocardial ischemia. It is done through a pressure guidewire delivered to the lesion of the coronary artery to measure the ratio of mean distal coronary pressure to mean aortic pressure under hyperemic flow. FFR is a highly reliable method in assessing the functional significance of coronary stenosis. However, due to the complicated procedure and requirement of pharmacological maximal vasodilation, it is difficult to promote the use of FFR. In recent years, quantitative flow ratio (QFR) based on 3-dimensional vessel reconstructions and hemodynamic estimates has been proposed as a novel method for physiological lesion assessment. QFR is a wire-free method for computation of virtual FFR. It shows good diagnostic accuracy compared with FFR, and reduces the costs, risks and time required by surgery. There is great potential of development for using QFR as a non-invasive functional assessment of coronary lesions. In this research, a semi-automatic system was established to detect the QFR of coronary arteries. Firstly, the frame of angiography was manually selected through the graphical user interface, and the image segmentation was applied to extract the vascular structure. Secondly, after selecting the region of interest of coronary artery, the corresponding 3-dimentional mesh model would be reconstructed automatically by projection and the lesion data were exported at the same time. Finally, the blood vessel model was imported to the computational fluid dynamics simulation software for hemodynamic analysis, so as to calculate the pressure ratio of the distal coronary pressure to the proximal coronary pressure, and evaluated the physiological function of lesion in a non-invasive way. In this research, patients who undergone coronary angiography were included as sample tests, and the simulation results were given a preliminary inspection. The results show that the calculated simulation values are in line with the main trend of clinical data, and the overall operation time of the system could be completed within 4 minutes, which significantly reduces the time and costs of surgery, and provides physicians with auxiliary tools for diagnosing coronary artery stenosis and appropriate treatment methods.