active flexure

简明释义

1. 活动挠褶; 2. 主动挠褶;

英英释义

例句

1.The design of the bridge incorporates an active flexure 主动弯曲 mechanism to accommodate thermal expansion.

这座桥的设计采用了一个主动弯曲 active flexure 机制，以适应热膨胀。

2.Engineers are studying the active flexure 主动弯曲 response of materials under varying loads.

工程师们正在研究材料在不同载荷下的主动弯曲 active flexure 响应。

3.The active flexure 主动弯曲 system allows for real-time adjustments in response to environmental changes.

该主动弯曲 active flexure 系统允许实时调整以响应环境变化。

4.In architectural design, active flexure 主动弯曲 can create dynamic and adaptable structures.

在建筑设计中，主动弯曲 active flexure 可以创造动态和适应性强的结构。

5.The robotic arm uses active flexure 主动弯曲 joints to enhance its range of motion.

这个机器人手臂使用主动弯曲 active flexure 关节来增强其运动范围。

作文

In the field of engineering and design, understanding various mechanical phenomena is crucial for creating efficient and effective structures. One such phenomenon is the concept of active flexure, which refers to the ability of a material or structure to bend and deform in response to applied forces while actively controlling that deformation. This is particularly important in applications where precision and adaptability are required, such as in robotics, aerospace, and even in everyday devices like smartphones. Active flexure allows these systems to respond dynamically to changes in their environment, enhancing functionality and performance.For instance, consider a robotic arm that needs to manipulate objects of varying shapes and weights. If the arm were rigid, it would struggle to grasp items securely without damaging them. However, by incorporating active flexure into its design, the arm can adjust its grip based on the object's characteristics. This capability not only improves the efficiency of the task but also minimizes the risk of damage to both the object and the robotic arm itself.Another application of active flexure can be found in the aerospace industry. Aircraft wings are designed to flex during flight, allowing them to withstand turbulent conditions while maintaining structural integrity. Engineers utilize materials that exhibit active flexure properties to ensure that wings can bend without breaking, thereby enhancing safety and performance. This flexibility also contributes to fuel efficiency, as a well-designed wing can optimize airflow, reducing drag.In addition, active flexure plays a significant role in the development of smart materials, such as shape memory alloys and polymers. These materials can change shape or stiffness in response to external stimuli, such as temperature or electric fields. By harnessing active flexure, designers can create innovative solutions that adapt to their surroundings, leading to advancements in various fields, including medicine, where devices can conform to the human body for better treatment outcomes.Moreover, the concept of active flexure extends beyond traditional engineering applications. In architecture, for example, buildings designed with flexible materials can better withstand earthquakes and other natural disasters. The ability to absorb and dissipate energy through active flexure can significantly reduce structural damage and enhance occupant safety.In conclusion, active flexure is a vital concept that underpins many modern technologies and designs. Its ability to allow structures and materials to bend and adapt under stress not only improves functionality but also enhances safety and efficiency across various industries. As technology continues to evolve, the integration of active flexure into new designs will undoubtedly lead to innovative solutions that address complex challenges in our world today.

在工程和设计领域，理解各种机械现象对于创造高效和有效的结构至关重要。其中一个现象是主动弯曲的概念，它指的是材料或结构在施加力的情况下弯曲和变形的能力，同时主动控制这种变形。这在需要精确和适应性的应用中尤为重要，例如在机器人技术、航空航天，甚至在日常设备如智能手机中。主动弯曲使这些系统能够动态响应环境的变化，从而增强功能和性能。例如，考虑一个需要操作不同形状和重量物体的机器人手臂。如果手臂是刚性的，它将难以安全地抓住物体而不损坏它们。然而，通过在设计中加入主动弯曲，手臂可以根据物体的特性调整其抓握。这种能力不仅提高了任务的效率，还最大限度地降低了对物体和机器人手臂本身造成损害的风险。主动弯曲的另一个应用可以在航空航天行业找到。飞机机翼在飞行中被设计成弯曲，以承受动荡条件，同时保持结构完整性。工程师利用具有主动弯曲特性的材料来确保机翼在弯曲时不会断裂，从而增强安全性和性能。这种灵活性还促进了燃油效率，因为设计良好的机翼可以优化气流，减少阻力。此外，主动弯曲在智能材料的发展中也发挥着重要作用，例如形状记忆合金和聚合物。这些材料可以根据外部刺激（如温度或电场）改变形状或刚度。通过利用主动弯曲，设计师可以创造出适应周围环境的创新解决方案，从而推动包括医学在内的各个领域的进步，在这些领域中，设备可以更好地适应人体以实现更好的治疗效果。此外，主动弯曲的概念超越了传统工程应用。在建筑学中，例如，使用灵活材料设计的建筑可以更好地抵御地震和其他自然灾害。通过主动弯曲吸收和耗散能量的能力可以显著减少结构损坏并增强居住者的安全性。总之，主动弯曲是支撑许多现代技术和设计的重要概念。它允许结构和材料在压力下弯曲和适应，不仅提高了功能性，还增强了各个行业的安全性和效率。随着技术的不断发展，将主动弯曲整合到新设计中无疑会导致创新解决方案，解决我们今天世界中的复杂挑战。