shock impingement

简明释义

冲击波撞击

英英释义

例句

1.The engineer explained that the design must account for shock impingement to prevent structural failure.

工程师解释说，设计必须考虑冲击干涉以防止结构失效。

2.During testing, we observed significant shock impingement on the vehicle's chassis.

在测试过程中，我们观察到车辆底盘上有显著的冲击干涉。

3.To improve safety, manufacturers are researching ways to mitigate shock impingement in their products.

为了提高安全性，制造商正在研究减轻其产品中冲击干涉的方法。

4.The mechanics noted that shock impingement can accelerate the degradation of materials.

机械师指出，冲击干涉会加速材料的退化。

5.In robotics, shock impingement can lead to unexpected wear on components.

在机器人技术中，冲击干涉可能导致组件意外磨损。

作文

In the realm of engineering and physics, understanding the various forces and impacts that affect materials and structures is crucial. One such phenomenon is known as shock impingement. This term refers to the impact that occurs when a shock wave interacts with a surface or an object, leading to potential damage or deformation. The study of shock impingement is essential in fields ranging from aerospace engineering to civil construction, where the integrity of materials under stress is paramount.When a shock wave travels through a medium, it carries a significant amount of energy. This energy can cause localized stresses when the wave encounters an object. For instance, in aerospace applications, when a spacecraft re-enters the Earth's atmosphere, it experiences intense heat and pressure due to shock impingement. The shock waves generated by the high-speed entry can lead to severe thermal and mechanical stresses on the vehicle's surface. Engineers must carefully design materials that can withstand these conditions to ensure the safety and success of the mission.In civil engineering, shock impingement plays a critical role in the analysis of structures subjected to blasts or impacts. For example, buildings located near industrial areas may be at risk of explosive events. Understanding how shock waves propagate and interact with building materials helps engineers create safer structures that can absorb or deflect these forces. Advanced simulations and modeling techniques are often employed to predict the effects of shock impingement, allowing for better design strategies that enhance structural resilience.The implications of shock impingement extend beyond just engineering; they also touch upon safety protocols and disaster preparedness. For instance, in military applications, vehicles and equipment must be designed to endure the impacts of explosions or projectiles. Research into shock impingement helps in developing armor and protective materials that can mitigate damage and protect personnel. This knowledge is vital for ensuring operational effectiveness and safeguarding lives in high-risk environments.Moreover, the concept of shock impingement is not limited to physical structures. In biological systems, similar principles can apply. For example, understanding how shock waves affect human tissues during medical procedures, such as lithotripsy (a treatment for kidney stones), is essential for optimizing outcomes and minimizing damage to surrounding tissues. The careful application of shock impingement principles in this context can lead to improved patient care and recovery.In conclusion, shock impingement is a multifaceted concept that has significant implications across various disciplines. From aerospace engineering to civil safety and even medical applications, the understanding of how shock waves interact with materials is vital. As technology advances, the study of shock impingement will continue to evolve, leading to innovative solutions and enhanced safety measures in numerous fields. A thorough grasp of this phenomenon not only enriches our scientific knowledge but also paves the way for practical applications that can protect and improve lives.

在工程和物理的领域中，理解影响材料和结构的各种力量和冲击至关重要。其中一个现象被称为冲击冲击。这个术语指的是当冲击波与表面或物体相互作用时发生的影响，可能导致损坏或变形。研究冲击冲击在航空航天工程到土木建筑等领域是必不可少的，因为在压力下材料的完整性至关重要。当冲击波通过介质传播时，它携带着大量的能量。当波遇到物体时，这种能量可以造成局部应力。例如，在航空航天应用中，当航天器重新进入地球大气层时，由于冲击冲击，它会经历强烈的热量和压力。由于高速进入产生的冲击波可能导致飞行器表面严重的热和机械应力。工程师必须仔细设计能够承受这些条件的材料，以确保任务的安全和成功。在土木工程中，冲击冲击在分析受到爆炸或冲击的结构时发挥着关键作用。例如，位于工业区附近的建筑物可能面临爆炸事件的风险。理解冲击波如何传播并与建筑材料相互作用，帮助工程师创建更安全的结构，能够吸收或偏转这些力量。通常采用先进的模拟和建模技术来预测冲击冲击的影响，从而允许更好的设计策略以增强结构的韧性。冲击冲击的影响不仅限于工程；它们还涉及安全协议和灾难准备。例如，在军事应用中，车辆和设备必须设计成能够承受爆炸或弹药的冲击。对冲击冲击的研究有助于开发能够减轻损害和保护人员的装甲和保护材料。这一知识对于确保操作有效性和在高风险环境中保护生命至关重要。此外，冲击冲击的概念并不限于物理结构。在生物系统中，类似的原理也可以适用。例如，理解冲击波在医疗程序（如体外冲击波碎石术（治疗肾结石））中如何影响人体组织，对于优化结果和最小化对周围组织的损害至关重要。在这种情况下，谨慎应用冲击冲击原理可以改善患者护理和恢复。总之，冲击冲击是一个多方面的概念，在各个学科中具有重要意义。从航空航天工程到土木安全，甚至医学应用，理解冲击波如何与材料相互作用是至关重要的。随着技术的进步，冲击冲击的研究将继续发展，导致创新解决方案和在众多领域增强的安全措施。深入理解这一现象不仅丰富了我们的科学知识，还为保护和改善生活铺平了道路。