coefficient of adhesion

简明释义

粘附系数

英英释义

例句

1.Researchers are studying the coefficient of adhesion 附着系数 between different types of paints and surfaces.

研究人员正在研究不同类型的油漆与表面之间的附着系数 coefficient of adhesion。

2.In tire manufacturing, the coefficient of adhesion 附着系数 is crucial for ensuring safety on wet roads.

在轮胎制造中，附着系数 coefficient of adhesion对确保湿滑道路上的安全至关重要。

3.The engineer calculated the coefficient of adhesion 附着系数 to determine how well the materials would bond.

工程师计算了附着系数 coefficient of adhesion以确定材料的结合效果。

4.To improve grip, the athletes studied the coefficient of adhesion 附着系数 of their shoes on different surfaces.

为了提高抓地力，运动员们研究了他们鞋子在不同表面上的附着系数 coefficient of adhesion。

5.The coefficient of adhesion 附着系数 affects how well a label sticks to a bottle.

对于标签粘附在瓶子上的效果，附着系数 coefficient of adhesion影响很大。

作文

The concept of coefficient of adhesion is essential in understanding how different materials interact with each other. It refers to the measure of how well two surfaces stick together when they come into contact. This property is crucial in various fields, including engineering, materials science, and even everyday applications such as adhesives and coatings. To comprehend the significance of the coefficient of adhesion, we must explore its implications in practical scenarios.In engineering, the coefficient of adhesion plays a vital role in the design of structures and components. For instance, when engineers are tasked with selecting materials for bridges or buildings, they must consider how well these materials will adhere to one another under different environmental conditions. A higher coefficient of adhesion indicates a stronger bond, which can enhance the stability and longevity of a structure. Conversely, materials with a low coefficient of adhesion may lead to failures due to slippage or detachment, resulting in safety hazards.Moreover, the coefficient of adhesion is also significant in the manufacturing industry, particularly in the production of composite materials. These materials often combine two or more substances to achieve desired properties, such as increased strength or reduced weight. Understanding the coefficient of adhesion between these different components is crucial for ensuring that they work cohesively. If the adhesion is insufficient, the composite might not perform as expected, leading to product failure.In everyday life, the coefficient of adhesion is evident in the products we use regularly. For example, when applying glue, the effectiveness largely depends on the coefficient of adhesion between the adhesive and the surfaces being bonded. A high coefficient of adhesion ensures that the glue will hold effectively, while a low one may result in a weak bond that fails over time. This principle applies not only to glues but also to paints and sealants, where proper adhesion is necessary for performance.Furthermore, the coefficient of adhesion is crucial in the field of biomechanics, particularly in understanding how organisms interact with their environments. For instance, geckos are known for their ability to climb vertical surfaces and even walk on ceilings. Researchers have studied the coefficient of adhesion of their toe pads to understand the mechanisms behind this remarkable ability. The findings could inspire new technologies, such as advanced adhesives or climbing robots, by mimicking the natural adhesion properties of geckos.In conclusion, the coefficient of adhesion is a fundamental concept that influences various aspects of our lives, from engineering and manufacturing to everyday products and biological systems. By understanding this property, we can improve material selection, enhance product performance, and even innovate new technologies. The study of the coefficient of adhesion continues to be an important area of research, promising advancements that could benefit numerous industries and applications.

“粘附系数”这一概念在理解不同材料之间的相互作用中至关重要。它指的是两种表面接触时粘附良好的程度。这一特性在工程、材料科学甚至日常应用（如粘合剂和涂层）等多个领域中都至关重要。为了理解“粘附系数”的重要性，我们必须探索其在实际场景中的影响。在工程学中，“粘附系数”在结构和组件的设计中发挥着重要作用。例如，当工程师负责选择桥梁或建筑物的材料时，他们必须考虑这些材料在不同环境条件下的粘附性。较高的“粘附系数”表示更强的结合，这可以提高结构的稳定性和耐久性。相反，具有较低“粘附系数”的材料可能会导致由于滑动或脱落而发生故障，从而造成安全隐患。此外，“粘附系数”在制造业中也很重要，特别是在复合材料的生产中。这些材料通常结合两种或多种物质以达到所需的特性，例如增加强度或减少重量。了解这些不同组分之间的“粘附系数”对于确保它们协同工作至关重要。如果粘附不足，复合材料可能无法按预期性能运行，导致产品失败。在日常生活中，“粘附系数”在我们定期使用的产品中显而易见。例如，在涂抹胶水时，其有效性在很大程度上取决于粘合剂与被粘合表面之间的“粘附系数”。较高的“粘附系数”确保胶水能有效地粘合，而较低的则可能导致随着时间的推移形成弱连接。这一原理不仅适用于胶水，也适用于油漆和密封剂，其中正确的粘附性对性能至关重要。此外，“粘附系数”在生物力学领域也至关重要，特别是在理解生物体如何与其环境相互作用方面。例如，壁虎以其能够攀爬垂直表面甚至在天花板上行走而闻名。研究人员研究了它们的脚垫的“粘附系数”，以了解这种非凡能力背后的机制。这些发现可能会激发新技术的发展，例如先进的粘合剂或攀爬机器人，通过模仿壁虎的自然粘附特性。总之，“粘附系数”是一个基本概念，影响着我们生活的各个方面，从工程和制造到日常产品和生物系统。通过理解这一特性，我们可以改善材料选择、增强产品性能，甚至创新新技术。“粘附系数”的研究仍然是一个重要的研究领域，承诺为众多行业和应用带来进步。