The choice of aluminum alloys used as the interlayers significantly influences the interfacial bonding properties and dynamic impact mechanical properties of 7B53 aluminum alloy composite plates (7A52/interlayer/7A63). In this study, the influence mechanism of different aluminum alloy interlayer materials (7A01, 6061, 2024 aluminum alloy) on the interfacial metallurgical bonding quality and the dynamic mechanical behavior at high strain rates (1700−3200 s−1) was systematically investigated using tensile-shear tests, Charpy impact tests, split Hopkinson pressure bar (SHPB) tests, and scanning electron microscopy (SEM). The results show that the composite plate with the 6061 interlayer exhibits the optimal interfacial bonding performance, achieving a maximum shear strength of 109.6 MPa, which is 36.5 MPa higher than that of the plate with the 7A01 interlayer (73.1 MPa). This improvement is attributed to the fact that the 6061 alloy promotes the formation of fine and uniform grains at the interface, thereby effectively strengthening the interfacial region. SHPB tests reveal that the inhomogeneous deformation of the interlayer interrupts the penetration of cracks into the 7A52 layer and promotes crack deflection along the interface. The composite plate with the 7A01 interlayer shows low strain rate sensitivity. The plate with the 6061 interlayer, while decreases in flow stress due to thermal softening within the strain rate range of 1700–2700 s−1, maintains stable deformation under high-velocity impact owing to its excellent ductility. Compared to the composite plate with the 2024 interlayer, the plate with the 6061 interlayer achieves higher plastic strain while retaining relatively high yield strength. The 6061 interlayer composite plate successfully achieves an effective integration of the high toughness of 7A52 and the high strength of 7A63, providing an important theoretical basis for the design of impact-resistant protective structures for armored vehicles.
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University laboratories, serving as core venues for experimental teaching and scientific research, undertake the crucial mission of knowledge innovation, technological invention, and cultivating students' innovative consciousness and comprehensive competencies. However, laboratory safety management faces significant challenges due to disciplinary diversity, hazard source complexity, and high personnel mobility. To enhance the efficiency of laboratory safety risk prevention and control, achieving scientific, standardized, and professional safety management, this paper proposes a differentiated control strategy based on disciplinary characteristics and risk levels. Adopting a multi-pronged research methodology combining theoretical analysis with empirical case studies, this research investigates the implementation pathways and management system optimization for hierarchical and categorized laboratory safety management in universities.
First, a comprehensive theoretical framework for laboratory safety classification and grading is systematically analyzed, forming the foundation for developing a practical management system. Second, leveraging the practical experience of Chongqing University's laboratory management, the research constructs a hierarchical and categorized safety management system. This system integrates key components: dynamic hazard identification mechanisms, quantitative risk assessment methodologies, and continuous optimization of responsibility systems. The research employs analytical tools including Job Hazard Analysis (JHA) and Safety Check Lists (SCL) to rigorously identify potential hazards, establish detailed risk source inventories, and conduct thorough safety risk assessments. Furthermore, the implementation adheres to guiding principles encompassing comprehensiveness, objectivity, disciplinary specialization, dynamic adaptability, centralized oversight, scientific rigor, and the application of the highest standards. Through literature review, case analysis, and practical application, the research provides a holistic exploration of laboratory safety management optimization.
This research successfully develops a comprehensive hierarchical and categorized laboratory safety management system. Key innovations include: ① a dynamic hazard identification mechanism enabling real-time risk monitoring; ② a quantitative risk assessment module facilitating objective risk evaluation; and ③ an optimized responsibility system clarifying roles and responsibilities. The system enhances the safety hazard investigation mechanism, provides explicit risk control and emergency response guidelines, and establishes a “university-school-laboratory” three-tiered management responsibility framework. It also proposes a dynamic adjustment mechanism and standardized process for reviewing and updating laboratory classifications, ensuring adaptability. Implementing hierarchical and classified management significantly improves laboratory management efficiency, enabling precise and refined safety control.
This management mode not only helps reduce safety risks and enhance prevention capabilities but also promotes interdisciplinary collaboration and improves equipment utilization rates. However, persistent challenges include difficulties in implementing control systems, formulating tailored standards and regulations, mitigating human factors, and ensuring timely dynamic adjustments. Therefore, universities need to establish a comprehensive laboratory safety responsibility system, develop institution-specific standards and regulations, strengthen laboratory personnel training to enhance safety awareness and emergency response capabilities, and utilize modern technology to optimize dynamic adjustment mechanisms. These efforts are crucial for achieving scientific, standardized, and professional laboratory safety management.
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