Abstract: A viral vector delivery system for both respiratory and digestive tracts of pigs and an application thereof are provided. The viral vector delivery system includes a backbone plasmid and a helper plasmid. The backbone plasmid is produced by inserting a full-length cDNA of porcine enterovirus B (PEVB) into a pUC57 plasmid. The helper plasmid is produced by inserting a green fluorescent protein-coding gene into a plasmid pCAG-T7-polymerase. The viral vector delivery system can be constructed with high efficiency, can quickly cause a cytopathic effect (CPE) after infecting cells, has a viral titer up to 107.75 TCID50/mL, and can maintain high stability. A pathogenic epitope for the respiratory and digestive tracts of pigs is inserted into the backbone plasmid to produce a vaccine antigen, which is non-pathogenic, has high stability and a high viral titer, and allows a prominent immunization effect after being inoculated in pigs.

Abstract: This disclosure relates to a photovoltaic energy storage and power system and a three-phase power control method, apparatus and device for load(s). The three-phase power control method for load(s) in a photovoltaic energy storage and power system includes obtaining a drawing or feeding power of a grid, an charging or discharging power of energy storage, and a photovoltaic generation power; determining a generation power of an electric power system based on the drawing or feeding power of the grid, the charging or discharging power of the energy storage, and the photovoltaic generation power; and distributing the generation power of the electric power system evenly to load(s) of each phase to achieve three-phase dynamic balancing.

Abstract: The present disclosure belongs to the technical field of engineering machinery and relates to an engineering machinery equipment modeling method and apparatus. The engineering machinery equipment modeling method comprises the following steps: in response to a modeling request of a user, determining a subsystem that matches the user from a plurality of subsystems of the engineering machinery equipment; displaying to the user a modeling page of the subsystem that matches the user; constructing a model of the subsystem of the engineering machinery equipment on the modeling page on the basis of a model library which can be used by the user; and adding the subsystem model of the engineering machinery equipment into the model library. Modeling efficiency of engineering machinery equipment can be improved by means of the present method.

Abstract: A method for assessing fatigue damage and a fatigue life based on a crystal plastic welding process model. According to the new method, consideration is given to the effects of the crystal slip system and the polycrystal plastic strain on the welding process performance of the material. A welding process damage and fatigue life assessment model is established on the mesoscopic scale. The effect of microscopic characterizations of materials on the welding process performance, as well as on the fatigue damage and life of welded joints, can be studied from the mesoscopic point of view. The relationship between the welding process and the evolution of the material performance can be determined by the macro-mesoscopic coupling calculation model to further determine the effect and degree of welding processes on the fatigue damage and life of materials.

Abstract: A method for assessing fatigue damage and fatigue life based on Abaqus is provided. The micro-macroscopic scale coupled model is based on the macroscopic representative area and the microstructure characterization of the material, and the microscopic sub-model is established by the Voronoi algorithm. The algorithm has good cross-platform compatibility and portability, fundamentally solves the technical problem of micro-macroscopic multi-scale coupling and establishes and applies the multi-scale coupled model to the fatigue damage and life assessment. The micro-macroscopic multi-scale coupled fatigue damage and life assessment model and algorithm of the material is capable of both considering the fatigue damage evolution on a microscopic scale and assessing the fatigue life, as well as calculating and assessing the two physical parameters on a macroscopic scale, so as to predict the fatigue damage and life of the whole workpiece.

Abstract: A method for assessing fatigue damage and a fatigue life based on a crystal plastic welding process model. According to the new method, consideration is given to the effects of the crystal slip system and the polycrystal plastic strain on the welding process performance of the material. A welding process damage and fatigue life assessment model is established on the mesoscopic scale. The effect of microscopic characterizations of materials on the welding process performance, as well as on the fatigue damage and life of welded joints, can be studied from the mesoscopic point of view. The relationship between the welding process and the evolution of the material performance can be determined by the macro-mesoscopic coupling calculation model to further determine the effect and degree of welding processes on the fatigue damage and life of materials.