viscometric

简明释义

英[/ˌvɪskəˈmɛtrɪk/]美[/ˌvɪskəˈmɛtrɪk/]

adj. 测定粘度的

英英释义

单词用法

同义词

反义词

例句

1.The results of viscometric titration assay indicated that these compounds interacted with CT-DNA by intercalation.

粘度滴定实验表明该系列化合物与DNA以嵌插方式作用；

2.The results of viscometric titration assay indicated that these compounds interacted with CT-DNA by intercalation.

粘度滴定实验表明该系列化合物与DNA以嵌插方式作用；

3.The viscometric 粘度测量 results indicated a significant change in the fluid's properties after heating.

该粘度测量结果表明，加热后流体的性质发生了显著变化。

4.The viscometric 粘度测量 analysis revealed that the paint had an optimal viscosity for application.

该粘度测量分析显示，油漆具有最佳的涂抹粘度。

5.In the food industry, viscometric 粘度测量 techniques are essential for ensuring product consistency.

在食品行业，粘度测量技术对确保产品一致性至关重要。

6.Researchers used viscometric 粘度测量 methods to study the behavior of non-Newtonian fluids.

研究人员使用粘度测量方法研究非牛顿流体的行为。

7.The laboratory conducted a series of viscometric 粘度测量 tests to determine the flow properties of the new polymer.

实验室进行了系列的粘度测量测试，以确定新聚合物的流动特性。

作文

Viscometric measurements are crucial in various fields, particularly in chemistry and engineering. The term viscometric (粘度计的) refers to the methods used to determine the viscosity of a fluid. Viscosity is a measure of a fluid's resistance to flow, and understanding this property is essential for predicting how substances will behave in different conditions. For instance, in the food industry, the viscometric analysis of sauces and dressings helps manufacturers ensure that their products have the desired texture and consistency. Similarly, in the petroleum industry, knowing the viscosity of crude oil can influence how it is transported and refined.The process of viscometric measurement typically involves using a viscometer, an instrument designed to measure the viscosity of a fluid under specified conditions. There are several types of viscometers, including capillary, rotational, and falling ball viscometers, each suited for different applications. For example, capillary viscometers work by measuring the time it takes for a fluid to flow through a narrow tube, while rotational viscometers apply a torque to a spindle immersed in the fluid to measure its resistance to flow.In research settings, viscometric data can provide insights into the molecular structure of substances. By analyzing how viscosity changes with temperature or shear rate, scientists can infer information about the interactions between molecules in a solution. This is particularly important in polymer science, where the viscosity of a polymer solution can indicate its molecular weight and degree of entanglement.Moreover, the relevance of viscometric measurements extends to environmental science as well. For instance, understanding the viscosity of various liquids can aid in predicting the movement of pollutants in water bodies. If a chemical spill occurs, knowing how viscous the substance is can help determine how quickly it will spread and what mitigation strategies should be employed.With advancements in technology, modern viscometric techniques have become more sophisticated. Automated viscometers can now provide real-time data, allowing for more accurate and efficient measurements. This is particularly beneficial in industrial settings where maintaining consistent product quality is paramount. Additionally, the integration of software for data analysis has revolutionized how viscometric data is interpreted, making it easier for engineers and scientists to draw meaningful conclusions from their measurements.In conclusion, the significance of viscometric measurements cannot be overstated. From ensuring product quality in manufacturing to aiding scientific research and environmental protection, understanding viscosity is fundamental across multiple disciplines. As technology continues to evolve, the methods for measuring viscosity will likely become even more precise, opening new avenues for research and application. Therefore, a solid grasp of viscometric principles is essential for anyone involved in fields that deal with fluid dynamics or material properties.

粘度计测量在多个领域中至关重要，尤其是在化学和工程领域。术语viscometric（粘度计的）指的是用于确定流体粘度的方法。粘度是衡量流体流动阻力的一个指标，理解这一特性对于预测物质在不同条件下的行为至关重要。例如，在食品工业中，对酱汁和调味品进行viscometric分析有助于制造商确保其产品具有所需的质地和一致性。同样，在石油工业中，了解原油的粘度可以影响其运输和精炼方式。viscometric测量的过程通常涉及使用粘度计，这是一种旨在在特定条件下测量流体粘度的仪器。有几种类型的粘度计，包括毛细管粘度计、旋转粘度计和落球粘度计，每种都适合不同的应用。例如，毛细管粘度计通过测量流体流过狭窄管道所需的时间来工作，而旋转粘度计则对浸入流体中的轴施加扭矩，以测量其流动阻力。在研究环境中，viscometric数据可以提供有关物质分子结构的见解。通过分析粘度如何随温度或剪切速率变化，科学家可以推断出溶液中分子之间相互作用的信息。这在聚合物科学中尤为重要，因为聚合物溶液的粘度可以指示其分子量和缠结程度。此外，viscometric测量的相关性还扩展到环境科学。例如，了解各种液体的粘度可以帮助预测污染物在水体中的运动。如果发生化学泄漏，了解物质的粘度可以帮助确定其扩散速度及应采取的缓解策略。随着技术的进步，现代的viscometric技术变得更加复杂。自动化粘度计现在可以提供实时数据，从而实现更准确和高效的测量。这在工业环境中特别有益，因为保持产品质量的一致性至关重要。此外，数据分析软件的集成彻底改变了viscometric数据的解释方式，使工程师和科学家更容易从测量中得出有意义的结论。总之，viscometric测量的重要性不容小觑。从确保制造中的产品质量到帮助科学研究和环境保护，理解粘度在多个学科中都是基础。因此，扎实掌握viscometric原理对于任何涉及流体动力学或材料特性的领域的人来说都是必不可少的。