deformable

简明释义

英[/dɪˈfɔrməbl/]美[/dɪˈfɔrməbl/]

adj. 可变形的

英英释义

单词用法

同义词

反义词

例句

1.IF a body is deformable, as all are to some extent, the deformation depends upon the point of application of the force.

如果一物体是可以变形的(所有物体都或多或少可以变形)，那么这种形变就取决于力的作用点。

2.This is great for non-deformable objects like, say, barrels and crates.

它非常适合没有变形的物体，例如枪炮，或是箱子。

3.Introduction to statics and the mechanics of deformable solids.

介绍静力学和固体形变力学。

4.In this paper, a new method of deformable image matching based on hybrid elastic models is proposed.

为此提出了一种利用混合弹性模型来解决图象变形匹配问题的新方法。

5.The equilibrium equations of growing deformable body based on the continuum model were established.

本文探讨了生长变形体连续介质模型的平衡理论框架。

6.Meanwhile, a non deformable, double directional cutting method for shearing tube was pointed out.

同时进一步提出了钢管的无变形剪切方法—双向切割法。

7.The new material is highly deformable, allowing it to be shaped into various forms without breaking.

这种新材料具有很高的可变形性，可以在不破裂的情况下被塑造成各种形状。

8.Engineers are developing deformable structures that can withstand earthquakes.

工程师们正在开发能够承受地震的可变形结构。

9.The deformable robots can adapt their shape to navigate through tight spaces.

这些可变形机器人可以调整形状以便在狭窄的空间中导航。

10.In computer graphics, deformable models are used to create realistic animations.

在计算机图形学中，可变形模型用于创建逼真的动画效果。

11.The deformable foam in the mattress provides excellent support and comfort.

床垫中的可变形泡沫提供了极好的支撑和舒适感。

作文

In the realm of engineering and materials science, the concept of deformable materials plays a crucial role in various applications. A deformable material is one that can change its shape or size when subjected to external forces, without breaking or losing its inherent properties. This characteristic is essential for designing structures that can withstand dynamic loads, such as bridges and buildings. For instance, when considering the construction of a bridge, engineers must select materials that are not only strong but also deformable. This ensures that the bridge can flex and absorb energy from wind or seismic activities, thereby preventing catastrophic failures. The importance of deformable materials extends beyond civil engineering. In the field of robotics, for example, engineers often utilize deformable components to create robots that can adapt to their environments. Soft robotics is an emerging area that focuses on creating robots with deformable bodies that can navigate through tight spaces or handle delicate objects without causing damage. By employing deformable materials, these robots can mimic natural movements, making them more efficient and versatile. Moreover, the medical field has also benefited from the study of deformable materials. For instance, prosthetics and implants often incorporate deformable elements to ensure comfort and functionality for the user. These materials can adapt to the movements of the body, providing a more natural experience for individuals who rely on such devices. The ability of a material to be deformable allows for better integration with biological tissues, which is critical for the success of many medical procedures. Despite the advantages of deformable materials, there are challenges associated with their use. One of the primary concerns is the durability of these materials under repeated stress. Engineers must carefully analyze the performance of deformable materials to ensure that they can withstand long-term use without degrading. This requires extensive testing and simulation to predict how these materials will behave over time. In conclusion, the study of deformable materials is vital across multiple disciplines, including engineering, robotics, and medicine. Their ability to change shape without losing integrity makes them invaluable in applications where flexibility and resilience are required. As technology continues to advance, the development of new deformable materials will likely lead to innovative solutions that enhance our daily lives. Understanding the principles governing deformable materials will be essential for future engineers and scientists as they tackle complex challenges and push the boundaries of what is possible.

在工程和材料科学领域，可变形的材料概念在各种应用中发挥着至关重要的作用。可变形的材料是指在外力作用下可以改变其形状或大小，而不会断裂或失去固有特性的材料。这一特性对于设计能够承受动态载荷的结构（如桥梁和建筑物）至关重要。例如，在考虑桥梁建设时，工程师必须选择不仅强度高而且具有可变形的材料。这确保了桥梁能够弯曲并吸收来自风或地震活动的能量，从而防止灾难性故障。 可变形的材料的重要性超越了土木工程领域。在机器人技术领域，例如，工程师经常利用可变形的组件来创建能够适应其环境的机器人。软机器人是一个新兴领域，专注于创建具有可变形的身体的机器人，这些机器人可以在狭小空间中导航或处理易损物体而不造成损坏。通过采用可变形的材料，这些机器人能够模拟自然运动，使其更加高效和多功能。 此外，医疗领域也从可变形的材料研究中受益匪浅。例如，假肢和植入物通常结合了可变形的元素，以确保用户的舒适性和功能性。这些材料可以适应身体的运动，为依赖这些设备的个人提供更自然的体验。材料的可变形的能力使其能够更好地与生物组织结合，这是许多医疗程序成功的关键。 尽管可变形的材料具有诸多优点，但其使用也面临挑战。其中一个主要问题是这些材料在重复应力下的耐用性。工程师必须仔细分析可变形的材料的性能，以确保它们能够在长期使用中不降解。这需要广泛的测试和模拟，以预测这些材料随时间的表现。 总之，可变形的材料的研究在多个学科中至关重要，包括工程、机器人和医学。它们在不失去完整性的情况下改变形状的能力使其在需要灵活性和韧性的应用中不可或缺。随着技术的不断进步，新可变形的材料的发展可能会带来创新解决方案，改善我们的日常生活。理解支配可变形的材料的原理对未来的工程师和科学家在应对复杂挑战和推动可能性的边界至关重要。