deformability

简明释义

英[/dɪˌfɔrməˈbɪləti/]美[/dɪˌfɔrməˈbɪləti/]

n. 可变形性

英英释义

单词用法

同义词

反义词

例句

1.Results Ethosomal system with good fluidity, deformability and high trapping rate is a stable carrier for transdermal delivery.

结论作为经皮给药的载体，醇质体有良好的应用前景和开发价值。

2.Erythrocyte deformability is the significant characteristic of some diseases.

红细胞的变形能力是某些疾病的重要特征。

3.There is no uniform standard to evaluating molding sand's deformability currently.

目前对型砂退让性还没有一个统一的评价标准。

4.CONCLUSION: the acute focal cerebral ischemic injury leads to the abnormal leukocyte rheology and declining of deformability.

结论：急性局灶性脑缺血损伤中有白细胞流变学异常，变形能力下降。

5.Objective To explore the the relationship between senescent erythrocyte deformability and lipid composition, spectrin content (sp) of erythrocyte membrane.

目的探讨老化红细胞变形能力与红细胞膜磷脂成分和收缩蛋白(SP)含量的关系。

6.From the general characteristics of cognition and aesthetic perception, perception towards colors, lines, sounds and shapes inevitably carries on deformability.

从认识的一般特性及美感的特性来看，人对色彩、形态、线条、声音等感知必然带有变形性。

7.Changes in erythrocyte deformability after burn injury were studied with an animal model of mild burn injury.

本文用轻度烧伤动物模型研究了烧伤后红细胞变形性的变化。

8.The deformability of the material allows it to absorb impacts without breaking.

该材料的变形能力使其能够在不破裂的情况下吸收冲击。

9.Engineers must consider the deformability of the structure when designing earthquake-resistant buildings.

工程师在设计抗震建筑时必须考虑结构的变形能力。

10.The deformability of rubber makes it an ideal material for seals and gaskets.

橡胶的变形能力使其成为密封件和垫圈的理想材料。

11.In biomechanics, the deformability of tissues plays a crucial role in their function.

在生物力学中，组织的变形能力在其功能中起着至关重要的作用。

12.Testing the deformability of metals helps manufacturers ensure quality control.

测试金属的变形能力帮助制造商确保质量控制。

作文

In the realm of materials science and engineering, the term deformability plays a crucial role in understanding how different substances respond to external forces. Deformability refers to the ability of a material to undergo deformation when subjected to stress. This characteristic is essential for engineers and designers as they select materials for various applications, ranging from construction to manufacturing. The deformability of a material can significantly influence its performance, durability, and suitability for specific tasks.For instance, metals are often chosen for their high deformability under tensile stress, which allows them to be shaped and molded into various forms without breaking. This property is particularly important in industries such as automotive and aerospace, where components must withstand significant forces while maintaining their structural integrity. On the other hand, materials with low deformability, such as ceramics, may be preferred for applications that require rigidity and resistance to wear, even though they may be more prone to fracture under stress.The deformability of a material is influenced by several factors, including its microstructure, temperature, and strain rate. For example, at elevated temperatures, many metals exhibit increased deformability, allowing them to be easily formed into complex shapes. This phenomenon is utilized in processes such as hot forging and extrusion, where materials are shaped while they are still hot. Understanding these factors enables engineers to optimize processing conditions to achieve desired material properties.Moreover, the concept of deformability extends beyond traditional materials to include polymers and composites. Polymers often display unique deformability characteristics, such as elasticity, which allows them to return to their original shape after deformation. This property is vital in applications such as packaging and cushioning materials, where flexibility and resilience are required. Composites, on the other hand, can be engineered to possess tailored deformability by combining different materials, thus enhancing their overall performance.In the context of structural engineering, understanding deformability is critical for ensuring safety and stability. Engineers must account for how structures will deform under loads, which can affect their load-bearing capacity and longevity. The study of deformability helps in predicting failure modes and designing structures that can accommodate expected deformations without compromising safety.In conclusion, the concept of deformability is fundamental in various fields, including materials science, engineering, and design. Its implications are far-reaching, affecting everything from the selection of materials to the design of safe and efficient structures. A comprehensive understanding of deformability allows engineers to innovate and create solutions that meet the demands of modern society, ensuring that materials perform optimally under a range of conditions. As technology advances, the study of deformability will continue to evolve, leading to new materials and applications that push the boundaries of what is possible in engineering and design.

在材料科学和工程领域，术语deformability（变形能力）在理解不同物质如何响应外部力方面起着至关重要的作用。Deformability指的是材料在受到应力时发生变形的能力。这一特性对工程师和设计师至关重要，因为他们在选择各种应用的材料时，从建筑到制造，deformability会显著影响材料的性能、耐久性和适用性。例如，金属通常因其在拉伸应力下的高deformability而被选中，这使得它们可以在不破裂的情况下被塑造成各种形状。这一特性在汽车和航空航天等行业尤为重要，在这些行业中，组件必须承受显著的力量，同时保持其结构完整性。另一方面，具有低deformability的材料，如陶瓷，可能更适合用于要求刚性和耐磨性的应用，尽管它们在应力下更容易断裂。材料的deformability受多种因素的影响，包括其微观结构、温度和应变速率。例如，在高温下，许多金属表现出增强的deformability，使得它们能够轻松地形成复杂的形状。这种现象在热锻造和挤压等工艺中得到了利用，在这些工艺中，材料在仍然热的时候被塑造。理解这些因素使工程师能够优化加工条件，以实现所需的材料特性。此外，deformability的概念不仅限于传统材料，还包括聚合物和复合材料。聚合物通常表现出独特的deformability特性，例如弹性，使它们在变形后能够恢复到原始形状。这一特性在包装和缓冲材料等应用中至关重要，这些应用需要灵活性和韧性。而复合材料则可以通过结合不同材料来设计出具有定制deformability的特性，从而增强其整体性能。在结构工程的背景下，理解deformability对于确保安全和稳定至关重要。工程师必须考虑结构在负载下的变形方式，这可能会影响其承载能力和使用寿命。对deformability的研究有助于预测失效模式，并设计出能够在不妨碍安全的情况下容纳预期变形的结构。总之，deformability的概念在材料科学、工程和设计等多个领域都是基础性的。其影响广泛，涉及从材料选择到安全高效结构设计的方方面面。全面理解deformability使工程师能够创新并创造出满足现代社会需求的解决方案，确保材料在各种条件下的最佳性能。随着技术的进步，deformability的研究将继续发展，推动新材料和应用的出现，拓展工程和设计领域的可能性。