thixotropic filler

简明释义

触变填料

英英释义

例句

1.The thixotropic filler used in the adhesive provided excellent bonding strength without running.

用于粘合剂的触变性填料提供了优异的粘合强度而不会流动。

2.In the art studio, the artist preferred a thixotropic filler for its ability to hold shapes without sagging.

在艺术工作室，艺术家更喜欢使用触变性填料，因为它能够保持形状而不下垂。

3.When mixing the paint, adding a thixotropic filler helped achieve the desired viscosity.

在混合油漆时，添加触变性填料有助于达到所需的粘度。

4.The engineers tested a new thixotropic filler for its performance in extreme temperatures.

工程师们测试了一种新的触变性填料在极端温度下的表现。

5.The construction team decided to use a thixotropic filler for the wall repairs, ensuring a smooth finish.

施工队决定使用触变性填料进行墙壁修复，以确保光滑的表面。

作文

In the world of materials science and engineering, the term thixotropic filler refers to a unique type of additive that exhibits a special property: it becomes less viscous under shear stress and returns to its original viscosity when at rest. This characteristic makes thixotropic fillers particularly valuable in various applications, including paints, coatings, and adhesives. Understanding how these fillers work can greatly enhance the performance of products across different industries.The fundamental principle behind thixotropic fillers is their ability to change consistency based on applied force. When stirred or shaken, these fillers become more fluid, allowing them to spread easily over surfaces or mix uniformly with other components. Once the force is removed, they revert to a thicker state, which helps maintain stability and prevents sagging or dripping. This behavior is especially beneficial in applications where control over flow and application is crucial.For instance, in the paint industry, using thixotropic fillers can lead to improved application properties. When a painter uses a brush or roller, the mechanical action reduces the viscosity of the paint, enabling smooth application. However, once the paint is on the surface, the thixotropic filler ensures that the paint does not run or drip, providing a uniform finish. This property is also advantageous in preventing settling of pigments during storage, ensuring that the paint remains consistent over time.Moreover, thixotropic fillers play a significant role in the formulation of adhesives. Many adhesives need to be applied in specific amounts and locations without running or spilling. The thixotropic nature of these fillers allows for precise application, making them ideal for construction, automotive, and electronics industries. For example, in automotive manufacturing, adhesives with thixotropic fillers can be applied to intricate parts without compromising the assembly process.Another area where thixotropic fillers are gaining traction is in the field of 3D printing. As the technology evolves, the demand for materials that can maintain shape and structure during the printing process has increased. Thixotropic fillers provide the necessary viscosity control, allowing for smoother layer deposition and reducing the risk of defects in the final product. This capability is essential for creating complex geometries and achieving high-quality prints.In summary, the incorporation of thixotropic fillers into various formulations can significantly improve the performance and usability of products. Their unique ability to alter viscosity under shear stress makes them indispensable in industries ranging from coatings to adhesives and even advanced manufacturing techniques like 3D printing. As research continues to explore new applications and formulations, the importance of thixotropic fillers will only grow, highlighting the need for engineers and scientists to understand and leverage this fascinating material property.In conclusion, the understanding and mastery of thixotropic fillers is crucial for anyone involved in material development. By comprehending their behavior and potential applications, professionals can innovate and create products that meet the ever-evolving demands of consumers and industries alike. As we move forward, the role of thixotropic fillers will undoubtedly continue to expand, paving the way for new advancements in material science.

在材料科学和工程领域，术语触变性填料指的是一种独特的添加剂，它具有特殊的性质：在剪切应力下黏度降低，而在静止状态下又恢复到原来的黏度。这一特性使得触变性填料在涂料、涂层和粘合剂等各种应用中尤为宝贵。理解这些填料的工作原理可以大大增强各行各业产品的性能。触变性填料的基本原理是它们能够根据施加的力量改变稠度。当搅拌或摇动时，这些填料变得更加流动，便于在表面上均匀涂抹或与其他成分混合。一旦施加的力量被移除，它们又会恢复到更厚的状态，这有助于保持稳定性并防止下垂或滴落。这种特性在需要控制流动和应用的场合尤其有益。例如，在涂料行业中，使用触变性填料可以改善涂抹性能。当画家使用刷子或滚筒时，机械作用减少了涂料的黏度，使其能够顺利涂抹。然而，一旦涂料涂在表面上，触变性填料确保涂料不会流淌或滴落，从而提供均匀的表面效果。这一特性在储存过程中也有助于防止颜料沉淀，确保涂料在时间上的一致性。此外，触变性填料在粘合剂的配方中也发挥着重要作用。许多粘合剂需要以特定的量和位置进行涂抹，而不发生流动或溢出。这些填料的触变特性允许精确应用，使其成为建筑、汽车和电子行业的理想选择。例如，在汽车制造中，含有触变性填料的粘合剂可以应用于复杂的部件而不影响组装过程。另一个触变性填料日益受到关注的领域是3D打印。随着技术的发展，对能够在打印过程中保持形状和结构的材料的需求不断增加。触变性填料提供了必要的黏度控制，使得层的沉积更加平滑，并减少最终产品缺陷的风险。这一能力对于创建复杂的几何形状和实现高质量打印至关重要。总之，将触变性填料纳入各种配方中，可以显著提高产品的性能和可用性。它们在剪切应力下改变黏度的独特能力使其在涂料、粘合剂甚至先进制造技术（如3D打印）等行业中不可或缺。随着研究继续探索新的应用和配方，触变性填料的重要性只会增加，强调了工程师和科学家理解和利用这一迷人材料特性的必要性。最后，理解和掌握触变性填料对任何参与材料开发的人来说都是至关重要的。通过理解它们的行为和潜在应用，专业人士可以创新并创造满足消费者和行业不断变化需求的产品。随着我们向前发展，触变性填料的角色无疑将继续扩大，为材料科学的新进展铺平道路。