excessive elastic deformability

简明释义

过大弹性变性

英英释义

例句

1.The research showed that excessive elastic deformability in certain polymers can enhance their performance in flexible electronics.

研究表明，某些聚合物中的过度弹性变形能力可以增强其在柔性电子产品中的性能。

2.In engineering applications, excessive elastic deformability can lead to structural instability if not properly managed.

在工程应用中，如果管理不当，过度弹性变形能力可能导致结构不稳定。

3.The design of the bridge had to account for the excessive elastic deformability of the materials used.

桥梁的设计必须考虑所用材料的过度弹性变形能力。

4.Manufacturers are concerned that excessive elastic deformability in their products could result in premature wear.

制造商担心产品中的过度弹性变形能力可能导致过早磨损。

5.The new rubber material shows excessive elastic deformability, which allows it to stretch significantly without breaking.

这种新型橡胶材料表现出过度弹性变形能力，使其能够在不破裂的情况下显著拉伸。

作文

In the realm of materials science, the concept of excessive elastic deformability plays a pivotal role in understanding how different materials respond to stress and strain. This term refers to the ability of a material to undergo significant elastic deformation when subjected to external forces without permanently changing its shape. While some degree of elastic deformability is desirable in many applications, excessive elastic deformability can lead to challenges in structural integrity and performance.To illustrate this point, consider the use of rubber in various engineering applications. Rubber is known for its remarkable elasticity, allowing it to stretch and return to its original shape. However, if rubber exhibits excessive elastic deformability, it may not provide the necessary support or stability required in certain structures. For example, in the construction of bridges or buildings, materials must maintain their shape under load to ensure safety and functionality. If a supporting beam made of rubber were to deform excessively, it could compromise the entire structure, leading to catastrophic failures.Moreover, in the field of biomechanics, excessive elastic deformability can have significant implications for the design of prosthetics and orthotics. Prosthetic limbs are often designed to mimic the natural movement of human limbs. However, if the materials used in these devices exhibit excessive elastic deformability, they may not provide adequate support or responsiveness during movement. This can result in discomfort for the user and limit the effectiveness of the prosthetic.The challenge, therefore, lies in finding a balance between sufficient elasticity and preventing excessive elastic deformability. Engineers and material scientists continually strive to develop new materials that offer the right combination of flexibility and stability. For instance, composite materials that blend fibers with polymers can achieve a desirable level of elasticity while minimizing the risk of excessive deformation.Additionally, understanding the factors that contribute to excessive elastic deformability is crucial for material selection in various applications. Factors such as temperature, humidity, and the rate of applied stress can significantly influence how a material behaves under load. By conducting thorough testing and analysis, engineers can predict how materials will perform in real-world conditions and make informed decisions about their use.In conclusion, while excessive elastic deformability may seem like a purely technical term, it has far-reaching implications across multiple fields. From construction to healthcare, the ability of materials to withstand stress without permanent deformation is critical to ensuring safety and functionality. As research continues to advance, the development of new materials that strike the right balance between elasticity and structural integrity will undoubtedly enhance our ability to innovate and improve the quality of life in various domains.

在材料科学领域，过度弹性变形能力的概念在理解不同材料如何应对应力和应变方面发挥着关键作用。这个术语指的是材料在受到外力作用时能够经历显著的弹性变形而不会永久改变其形状的能力。虽然在许多应用中适度的弹性变形能力是可取的，但过度弹性变形能力可能会导致结构完整性和性能方面的挑战。为了说明这一点，考虑橡胶在各种工程应用中的使用。橡胶以其卓越的弹性而闻名，允许其拉伸并恢复到原始形状。然而，如果橡胶表现出过度弹性变形能力，它可能无法在某些结构中提供所需的支持或稳定性。例如，在桥梁或建筑物的施工中，材料必须在负载下保持其形状，以确保安全和功能。如果用橡胶制成的支撑梁过度变形，它可能会危及整个结构，导致灾难性的失败。此外，在生物力学领域，过度弹性变形能力对假肢和矫形器的设计有重要影响。假肢通常被设计成模仿人类肢体的自然运动。然而，如果这些设备中使用的材料表现出过度弹性变形能力，它们可能无法在运动过程中提供足够的支持或响应。这可能导致用户的不适，并限制假肢的有效性。因此，挑战在于找到足够弹性与防止过度弹性变形能力之间的平衡。工程师和材料科学家不断努力开发新材料，以提供灵活性和稳定性的正确组合。例如，结合纤维和聚合物的复合材料可以在最小化过度变形风险的同时实现理想的弹性水平。此外，理解导致过度弹性变形能力的因素对于各种应用中的材料选择至关重要。温度、湿度和施加应力的速率等因素会显著影响材料在负载下的表现。通过进行全面的测试和分析，工程师可以预测材料在实际条件下的表现，并做出明智的使用决策。总之，虽然过度弹性变形能力可能看起来只是一个纯技术术语，但它在多个领域具有深远的影响。从建筑到医疗，材料在不发生永久变形的情况下承受应力的能力对于确保安全和功能至关重要。随着研究的持续推进，开发出在弹性与结构完整性之间取得适当平衡的新材料无疑将增强我们在各个领域创新和改善生活质量的能力。