biaxial

简明释义

英[baɪˈæksɪəl]美[baɪˈæksɪəl]

adj. 双轴的，双光轴的

英英释义

单词用法

同义词

反义词

例句

1.This study has laid a foundation for future research on members subjected to biaxial eccentric compression, biaxial shear and reversed cyclic torsion.

此项研究为反复扭矩作用下的双向压弯剪构件性能的研究打下了基础。

2.The model was successfully validated and used to simulate time-varying responses of engineered AF under shear and biaxial loading.

模型成功地被证实并使用于模仿在剪切和双轴向负荷下反应程度依时间变化的组织工程纤维环。

3.This theory can be extended to biaxial stress .

这个理论能推广到双轴应力。

4.In this paper, a relative criterion method is presented for analysing the elastic plastic stable crack propagation under biaxial loading conditions.

本文提出了一个用相对准则分析双向载荷下弹塑性裂纹稳定扩展的方法。

5.The simulation results show that both uniaxial compression and biaxial tension can enhance the hole mobility.

模拟结果显示：无论是单轴压应力还是双轴张应力，都使得空穴迁移率增大。

6.For both uniaxial and biaxial vibrating feeders, the optimization of operating parameters has been completed by means of the electronic computer.

应用电子计算机对单轴和双轴惯性振动出矿机分别进行了工作参数最优化分析。

7."World's fastest autofocus" with 11-point biaxial AF system.

全新更快的11点自动对焦，最猛的是统统都是十字对焦点。

8.Objective To study the effects of different treatment methods on the biaxial flexural strength of hot pressable ceramic.

目的研究不同处理方式对白榴石增强陶瓷的双轴弯曲强度的影响。

9.They are coupled with plastics calender for continuously producing PVC file, sheet, leatherette and film biaxial drawing etc.

相应的辅机与塑料压延机配套使用，可连续生产聚氯乙烯薄膜、薄片、人造革和拉伸拉幅膜等。

10.The biaxial 双轴 testing revealed that the material could withstand higher loads than previously expected.

双轴测试显示该材料能够承受比预期更高的负载。

11.We developed a model to simulate biaxial 双轴 deformation in the structure under various conditions.

我们开发了一个模型来模拟结构在各种条件下的双轴变形。

12.The biaxial 双轴 stretching method is commonly used in the production of films and membranes.

双轴拉伸方法通常用于薄膜和膜的生产。

13.In the experiment, we used a biaxial 双轴 loading system to apply forces in two directions simultaneously.

在实验中，我们使用了一个双轴加载系统，同时施加两个方向的力。

14.The material was tested under a biaxial 双轴 stress condition to evaluate its mechanical properties.

该材料在双轴应力条件下进行了测试，以评估其机械性能。

作文

In the field of materials science and engineering, understanding the mechanical properties of materials is crucial for various applications. One important concept that often arises is that of biaxial (双轴的) stress and strain. This term refers to a situation where a material is subjected to stresses in two different directions. Unlike uniaxial stress, which involves force applied in only one direction, biaxial (双轴的) stress considers the interaction of forces acting on a material from two perpendicular axes. This has significant implications in the design and analysis of materials used in construction, manufacturing, and aerospace industries.For example, consider a thin film used in electronic devices. When this film is subjected to thermal expansion or contraction, it experiences biaxial (双轴的) stress due to the constraints imposed by its substrate. The ability to accurately predict how these films will behave under biaxial (双轴的) conditions is essential for ensuring the reliability and longevity of electronic components. Engineers must account for the unique failure modes that can arise from such stresses, which may differ significantly from those observed under uniaxial conditions.Moreover, the concept of biaxial (双轴的) testing is vital in material characterization. In laboratory settings, materials are often tested under biaxial (双轴的) loading to determine their yield strength, ductility, and other mechanical properties. This type of testing provides a more comprehensive understanding of how materials will perform in real-world applications, where they are rarely subjected to simple, uniaxial loads.The importance of biaxial (双轴的) behavior extends beyond just mechanical properties; it also affects the thermal and electrical characteristics of materials. For instance, polymers can exhibit different thermal expansion coefficients when subjected to biaxial (双轴的) stress compared to uniaxial stress. This discrepancy can lead to warping or failure of components if not properly accounted for during the design phase.In the realm of structural engineering, biaxial (双轴的) stresses are critical in the analysis of beams, plates, and shells. Structures often experience complex loading scenarios where multiple forces act simultaneously. Understanding how these forces interact through biaxial (双轴的) analysis allows engineers to design safer and more efficient structures. For instance, in the design of bridges, the biaxial (双轴的) effects of wind loads and traffic loads must be considered to ensure the structure can withstand potential failure modes.In conclusion, the concept of biaxial (双轴的) stress and strain is fundamental in various fields, particularly in materials science and engineering. It encompasses a wide range of applications, from electronic devices to large-scale structural designs. A thorough understanding of biaxial (双轴的) behavior enables engineers and scientists to innovate and improve the performance of materials and structures. As technology continues to advance, the significance of biaxial (双轴的) analysis will only grow, making it an essential area of study for future engineers and researchers.

在材料科学和工程领域，理解材料的机械特性对于各种应用至关重要。一个常见的重要概念是biaxial（双轴的）应力和应变。这个术语指的是材料在两个不同方向上受到应力的情况。与仅在一个方向上施加力的单轴应力不同，biaxial（双轴的）应力考虑了作用在材料上的两个垂直轴上的力量的相互作用。这在建筑、制造和航空航天工业中设计和分析材料时具有重要意义。例如，考虑用于电子设备的薄膜。当该薄膜受到热膨胀或收缩时，由于其基底施加的约束，它会经历biaxial（双轴的）应力。准确预测这些薄膜在biaxial（双轴的）条件下的行为对于确保电子元件的可靠性和使用寿命至关重要。工程师必须考虑这种应力所引发的独特失效模式，这些模式可能与单轴条件下观察到的模式显著不同。此外，biaxial（双轴的）测试的概念在材料表征中至关重要。在实验室环境中，材料通常在biaxial（双轴的）载荷下进行测试，以确定其屈服强度、延展性和其他机械特性。这种类型的测试提供了对材料在现实世界应用中的表现的更全面的理解，因为它们很少受到简单的单轴载荷。biaxial（双轴的）行为的重要性超越了机械特性；它还影响材料的热和电特性。例如，当聚合物受到biaxial（双轴的）应力时，其热膨胀系数可能与单轴应力下不同。这种差异如果在设计阶段未能妥善考虑，可能导致组件的翘曲或失效。在结构工程领域，biaxial（双轴的）应力在梁、板和壳体的分析中至关重要。结构通常经历复杂的载荷场景，其中多个力量同时作用。通过biaxial（双轴的）分析理解这些力量如何相互作用，使工程师能够设计出更安全、更高效的结构。例如，在桥梁设计中，必须考虑风载荷和交通载荷的biaxial（双轴的）影响，以确保结构能够承受潜在的失效模式。总之，biaxial（双轴的）应力和应变的概念在各个领域，特别是在材料科学和工程中是基础性的。它涵盖了从电子设备到大规模结构设计的广泛应用。对biaxial（双轴的）行为的透彻理解使工程师和科学家能够创新并改善材料和结构的性能。随着技术的不断进步，biaxial（双轴的）分析的重要性只会增加，使其成为未来工程师和研究人员必须学习的关键领域。