While computational fluid dynamics (CFD) on blood flow are now widely accepted in quantitatively analyzing biomechanical and biomedical phenomena, so far most of the CFD-based studies have been focusing exclusively on some specific blood vessels or vascular segments under highly simplified physiological boundary conditions, and hardly consider the interactions among the interested region and the whole circulatory system. The cardiovascular system, however, is a closed-loop system where hemodynamics is an integrated result of the complicated interactions and plays an important role in hemodynamic regulations throughout the system. Therefore, a multi-scale hemodynamic simulator capable to evaluate the circulatory system in a synthetical manner is thought to be able to provide a physiologically realistic evaluation on the circulatory functions. A baseline for such a hemodynamic simulator requires development of a global arterial-and-venous tree model on a basis of the blood vessel morphology of the vascular system as well as the vessel-specific biomechanical properties. In this paper we present some preliminary results of a recently established vascular system database, involving 375 blood vessel models of 263 arteries and 112 veins, which are built up based on the Voxel-Man 3D Navigator, and of visualized blood flow patterns in some vessels of the global arterial-and-venous tree model.