air inhibition

简明释义

空气抑制作用

英英释义

例句

1.The artist noticed that air inhibition affected the drying time of her paint.

艺术家注意到，空气抑制影响了她油漆的干燥时间。

2.In 3D printing, air inhibition can cause uneven layers to form.

在3D打印中，空气抑制可能导致层的不均匀形成。

3.Proper ventilation is crucial to minimize air inhibition in chemical processes.

适当的通风对减少化学过程中的空气抑制至关重要。

4.To prevent air inhibition, use a cover while applying the resin.

为了防止空气抑制，在涂抹树脂时使用覆盖物。

5.During the experiment, we observed how air inhibition impacted the reaction rate.

在实验过程中，我们观察到空气抑制如何影响反应速率。

作文

In the world of science and technology, particularly in the fields of chemistry and material science, understanding various phenomena is crucial for innovation and development. One such phenomenon is air inhibition, which plays a significant role in processes involving polymerization and curing. Air inhibition refers to the interference that air can have on the curing process of certain materials, especially those that rely on chemical reactions to harden or set. This is particularly evident in the case of adhesives, coatings, and sealants that are exposed to atmospheric conditions during application.When considering the implications of air inhibition, it is essential to recognize its impact on the final properties of the material being used. For instance, when an adhesive is applied, the presence of air can prevent the adhesive from fully curing, leading to weaker bonds and compromised performance. This is because the oxygen in the air can react with the components of the adhesive, inhibiting the necessary chemical reactions that are required for proper curing. As a result, manufacturers must take steps to minimize air inhibition to ensure that their products perform as intended.One common method to combat air inhibition is to use specific formulations that are designed to be less sensitive to atmospheric conditions. These formulations may include additives that help to promote curing even in the presence of air. Additionally, applying these materials in a controlled environment, where humidity and temperature can be regulated, can significantly reduce the effects of air inhibition. By understanding the conditions that lead to this phenomenon, scientists and engineers can develop better materials that are more reliable and effective in real-world applications.Moreover, the concept of air inhibition extends beyond just adhesives. In the realm of 3D printing, for example, certain resins used in the process can also experience air inhibition, resulting in incomplete curing and defects in the printed object. This has led to advancements in printing technologies that either eliminate the exposure to air during the curing process or utilize different light sources to enhance curing efficiency. Addressing air inhibition is essential for ensuring high-quality output in additive manufacturing, which is becoming increasingly important across various industries.In conclusion, air inhibition is a critical factor that affects the performance and reliability of many materials used in modern applications. Understanding this phenomenon allows scientists and engineers to develop strategies to mitigate its effects, thereby improving the quality and effectiveness of products ranging from adhesives to 3D-printed objects. As technology continues to advance, the ability to control air inhibition will likely play a pivotal role in the future of material science and engineering. By addressing this challenge, we can pave the way for innovations that enhance our everyday lives, making products safer, stronger, and more efficient than ever before.

在科学和技术的世界中，特别是在化学和材料科学领域，理解各种现象对创新和发展至关重要。其中一个现象是空气抑制，它在涉及聚合和固化的过程中发挥着重要作用。空气抑制指的是空气对某些材料固化过程的干扰，尤其是那些依赖化学反应来硬化或设置的材料。这在暴露于大气条件下应用的粘合剂、涂料和密封剂的情况下尤为明显。考虑到空气抑制的影响，必须认识到它对所使用材料最终特性的影响。例如，当粘合剂被施加时，空气的存在可能会阻止粘合剂完全固化，从而导致粘结力减弱和性能受损。这是因为空气中的氧气可以与粘合剂的成分反应，抑制所需的化学反应，以实现适当的固化。因此，制造商必须采取措施来最小化空气抑制，以确保其产品按预期性能。应对空气抑制的一种常见方法是使用专门设计的配方，这些配方对大气条件的敏感性较低。这些配方可能包括一些添加剂，帮助促进固化，即使在空气存在的情况下。此外，在受控环境中施用这些材料，可以显著减少空气抑制的影响。通过理解导致这一现象的条件，科学家和工程师可以开发出更可靠、更有效的材料，适用于现实世界的应用。此外，空气抑制的概念不仅限于粘合剂。在3D打印领域，例如，某些用于该过程的树脂也可能经历空气抑制，导致固化不完全和打印对象缺陷。这促使了打印技术的进步，消除了固化过程中暴露于空气的情况，或利用不同的光源来提高固化效率。解决空气抑制问题对于确保增材制造中的高质量输出至关重要，而增材制造在各个行业中变得越来越重要。总之，空气抑制是影响许多现代应用中使用的材料性能和可靠性的关键因素。理解这一现象使科学家和工程师能够开发出减轻其影响的策略，从而提高从粘合剂到3D打印对象等产品的质量和有效性。随着技术的不断进步，控制空气抑制的能力在材料科学和工程的未来中可能发挥关键作用。通过解决这一挑战，我们可以为增强日常生活的创新铺平道路，使产品比以往任何时候都更安全、更强大和更高效。