uniaxially
简明释义
英[ˌjuːnɪˈæksɪəli]美[ˌjunɪˈækʃəli]
adv. 单向地
英英释义
以与单一轴线相关或沿单一轴线发生的方式。 |
单词用法
单轴拉伸 | |
单轴加载 | |
单轴对齐 | |
单轴取向材料 | |
单轴拉伸测试 | |
单轴各向异性特性 |
同义词
| 一维的 | The material was tested uniaxially to determine its tensile strength. | 该材料经过单轴测试以确定其抗拉强度。 | |
| 单向的 | In a unidirectional flow, the movement occurs in a single direction. | 在单向流动中,运动发生在一个方向上。 |
反义词
| 双轴向 | The material was tested biaxially to evaluate its strength in two directions. | 该材料经过双轴向测试,以评估其在两个方向上的强度。 | |
| 多轴向 | Multiaxially oriented films are used in various packaging applications. | 多轴向定向薄膜用于各种包装应用。 |
例句
1.The cool crystallization of uniaxially oriented PET was studied at different draw ratios and humidity by DSC.
采用DSC研究了不同拉伸比的单轴取向PET纤维在不同湿度下的冷结晶过程。
2.The characteristic equations of the guided modes in a uniaxially anisotropic left-handed material slab waveguide are derived.
推导了单轴各向异性左手平板波导的导模特征方程。
3.In this thesis we investigate the beam propagation and amphoteric refraction in a Uniaxially anisotropic crystal.
本文在理论上研究了单轴晶体中的光束传输和正负折射现象。
4.The characteristic equations of the guided modes in a uniaxially anisotropic left-handed material slab waveguide are derived.
推导了单轴各向异性左手平板波导的导模特征方程。
5.In the experiment, the samples were stretched uniaxially 单轴 to observe their deformation characteristics.
在实验中,样品被uniaxially 单轴拉伸,以观察它们的变形特性。
6.The researchers found that the material exhibited different behaviors when subjected uniaxially 单轴 versus biaxially.
研究人员发现,该材料在承受uniaxially 单轴与双轴时表现出不同的行为。
7.The material was tested for its strength when loaded uniaxially 单轴 to determine its failure point.
该材料在加载uniaxially 单轴时进行了强度测试,以确定其破坏点。
8.When testing the tensile strength, the specimen was pulled uniaxially 单轴 along its length.
在测试抗拉强度时,试样沿其长度uniaxially 单轴拉伸。
9.The mechanical properties of polymers are often measured uniaxially 单轴 to simplify the analysis.
聚合物的机械性质通常通过uniaxially 单轴测量,以简化分析。
作文
In the field of materials science, understanding the properties of various materials is crucial for their application in engineering and technology. One particular aspect that researchers often focus on is how materials behave under different types of stress and strain. A term that frequently arises in this context is uniaxially, which refers to the application of stress or strain in one direction only. This concept is fundamental when studying the mechanical properties of materials, as it allows scientists to isolate specific behaviors that occur when a material is subjected to forces along a single axis.When a material is tested uniaxially, it means that the forces acting upon it are applied in a straight line, rather than in multiple directions. This can be particularly important in understanding how materials respond to tensile or compressive forces. For example, in tensile testing, a sample is pulled apart from both ends, and the stress-strain relationship is recorded. The results of such tests provide valuable information about the strength, ductility, and elasticity of the material.The significance of uniaxially applied stress can also be seen in the manufacturing processes of various products. For instance, when metals are drawn into wires or sheets, they are often subjected to uniaxially directed forces. This process not only shapes the material but also alters its internal structure, enhancing its mechanical properties. Understanding how materials behave under uniaxially applied loads helps engineers design components that can withstand specific operational stresses without failing.Moreover, the concept of uniaxially applied forces extends beyond just mechanical testing. In the realm of geotechnical engineering, soil mechanics often involves analyzing how soil behaves when subjected to uniaxially applied loads. This is critical in construction projects where the stability of foundations relies on the ability of the soil to support structures without excessive deformation or failure.In addition to practical applications, the study of uniaxially stressed materials has led to advancements in theoretical models that predict material behavior under different loading conditions. These models are essential for developing new materials with enhanced properties, such as composites that can withstand higher stresses while remaining lightweight. As researchers continue to explore the implications of uniaxially applied forces, they contribute to the innovation of materials that meet the demands of modern engineering challenges.In conclusion, the term uniaxially is integral to the understanding of material behavior under stress. Whether in mechanical testing, manufacturing processes, or geotechnical applications, recognizing the effects of uniaxially applied forces is vital for engineers and scientists alike. By studying how materials respond to such stresses, we can improve existing materials and develop new ones that enhance performance and safety in various applications. The exploration of uniaxially stressed materials will undoubtedly continue to play a significant role in the advancement of technology and engineering solutions in the future.
在材料科学领域,理解各种材料的性质对其在工程和技术中的应用至关重要。研究人员经常关注的一个特定方面是材料在不同类型的应力和应变下的行为。在这个背景下,一个常出现的术语是uniaxially,它指的是仅在一个方向上施加应力或应变。这一概念在研究材料的机械性能时是基础性的,因为它使科学家能够隔离出材料在沿单一轴线施加力时发生的特定行为。当材料经过uniaxially测试时,意味着作用于其上的力是沿直线施加的,而不是在多个方向上。这在理解材料如何响应拉伸或压缩力时尤其重要。例如,在拉伸测试中,样品从两端被拉开,并记录应力-应变关系。这类测试的结果提供了关于材料强度、延展性和弹性的重要信息。uniaxially施加应力的意义在各种产品的制造过程中也得以体现。例如,当金属被拉制成线或片时,通常会受到uniaxially定向力的作用。这个过程不仅塑造了材料,还改变了其内部结构,增强了其机械性能。理解材料在uniaxially施加载荷下的行为有助于工程师设计能够承受特定操作应力而不发生失效的组件。此外,uniaxially施加力的概念不仅限于机械测试。在土木工程领域,土壤力学常常涉及分析土壤在uniaxially施加载荷下的行为。这在建筑项目中至关重要,因为基础的稳定性依赖于土壤支持结构的能力,而不会发生过度变形或失效。除了实际应用,uniaxially受应力材料的研究还推动了理论模型的发展,这些模型可以预测材料在不同加载条件下的行为。这些模型对于开发具有增强性能的新材料至关重要,例如能够承受更高应力的复合材料,同时保持轻量化。随着研究人员继续探索uniaxially施加力的影响,他们为新材料的创新做出了贡献,这些材料满足现代工程挑战的需求。总之,术语uniaxially对理解材料在应力下的行为至关重要。无论是在机械测试、制造过程还是土木工程应用中,认识到uniaxially施加力的影响对工程师和科学家来说都是至关重要的。通过研究材料如何响应这种应力,我们可以改善现有材料并开发出新的材料,从而提高各种应用中的性能和安全性。对uniaxially受应力材料的探索无疑将在未来技术和工程解决方案的进步中继续发挥重要作用。
