rheology

简明释义

[rɪˈɒlədʒi][riːˈɑːlədʒi]

n. [力] 流变学;液流学

英英释义

The branch of physics that deals with the flow and deformation of matter, particularly the study of the properties of materials that exhibit both viscous and elastic behavior.

研究物质流动和变形的物理学分支,特别是研究表现出粘性和弹性行为的材料性质。

单词用法

rheological properties

流变学特性

rheological behavior

流变行为

rheology testing

流变学测试

rheology of complex fluids

复杂流体的流变学

rheology in materials science

材料科学中的流变学

rheology and viscosity

流变学与粘度

同义词

viscoelasticity

粘弹性

The study of viscoelasticity is crucial for understanding polymer behavior.

研究粘弹性对于理解聚合物行为至关重要。

fluid mechanics

流体力学

Fluid mechanics principles can help in analyzing the flow properties of materials.

流体力学原理可以帮助分析材料的流动特性。

反义词

elasticity

弹性

The material exhibits high elasticity under stress.

该材料在应力下表现出高弹性。

rigidity

刚性

The rigidity of the structure prevents any deformation.

结构的刚性防止了任何变形。

例句

1.Rheology: The science that study the flowing property of liquids.

流动学:研究液体流动特性的科学。

2.Rheology properties and thermodynamics properties of the denaturalized hydrolyzed gelatin were studied in this paper.

本实验对改性水解明胶的流变学性质、热力学性质进行了研究。

3.Objective: This study evaluated the relationship between blood rheology and subungual microcirculation with abnormal lipoproteins.

前言:目的:探讨血脂异常与血液流变学、甲襞微循环的关系。

4.The effect of GBE50 on blood rheology parameter of rabbit indicated that it could prevent the thrombosis and promote thrombolysis.

GBE50对家兔血液流变学参数的影响的实验表明GBE50有预防血栓形成和促进血栓溶解作用。

5.Based on the rheology character of soil and stone, some rheology models is set forth.

从土石料的流变性质出发,阐述了几个流变模型。

6.The study of the law of Safety Rheology and Mutation establish a foundation for revealing the essence of the events safety .

事物“安全流变-突变”规律的研究为揭示事物的安全本质规律奠定了基础。

7.The efficacy, blood rheology and adverse reaction were compared.

进行疗效、血液流变学变化及不良反应比较。

8.Researchers are exploring the rheology of biological fluids to better understand human health.

研究人员正在探索生物液体的流变学,以更好地理解人类健康。

9.The study of rheology helps us understand how materials flow and deform under stress.

流变学的研究帮助我们理解材料在应力下如何流动和变形。

10.The rheology of concrete affects its workability and strength over time.

混凝土的流变学影响其可加工性和随时间的强度。

11.Engineers often apply rheology principles to improve the manufacturing processes of polymers.

工程师经常应用流变学原理来改善聚合物的制造过程。

12.In food science, rheology is crucial for analyzing the texture of sauces and creams.

在食品科学中,流变学对于分析酱料和奶油的质地至关重要。

作文

Rheology is a fascinating branch of science that deals with the flow and deformation of materials. It combines principles from physics, engineering, and material science to understand how substances behave under various conditions. The study of rheology (流变学) is essential for industries that work with complex fluids, such as food, cosmetics, and polymers. Understanding rheology (流变学) helps engineers and scientists design better products and processes by predicting how materials will respond to stress, strain, and temperature changes.One of the key concepts in rheology (流变学) is viscosity, which measures a fluid's resistance to flow. For instance, honey has a high viscosity compared to water, meaning it flows more slowly. This property is crucial in many applications, from manufacturing to cooking. By studying the rheology (流变学) of different substances, researchers can optimize formulations to achieve desired textures and consistencies. For example, in the food industry, understanding the rheology (流变学) of sauces can help create products that are appealing in both taste and texture.Another important aspect of rheology (流变学) is the behavior of materials under stress. Some materials exhibit elastic behavior, returning to their original shape after being deformed, while others show plastic behavior, where they permanently change shape. Many materials fall somewhere in between, displaying viscoelastic properties. This dual nature is particularly relevant in the development of new materials, such as those used in construction or manufacturing, where both strength and flexibility are required. By understanding the rheology (流变学) of these materials, engineers can tailor their properties to meet specific needs.In recent years, the application of rheology (流变学) has expanded into new fields such as biomedicine and nanotechnology. For example, the flow characteristics of blood can be studied using rheology (流变学), providing insights into various medical conditions such as thrombosis or atherosclerosis. Similarly, in nanotechnology, the behavior of nanomaterials can be analyzed through rheology (流变学), allowing for innovations in drug delivery systems and other applications.In conclusion, rheology (流变学) is a vital field that impacts numerous industries and scientific disciplines. Its principles help us understand the complex behaviors of materials, leading to advancements in product development and innovation. As we continue to explore the intricacies of rheology (流变学), we unlock new possibilities for creating better, more efficient materials and processes that enhance our daily lives. The importance of rheology (流变学) cannot be overstated, as it bridges the gap between theory and practical application, ultimately contributing to technological progress and improved quality of life.