interlamination

简明释义

英[/ˌɪntərˌlæmɪˈneɪʃən/]美[/ˌɪntərˌlæmɪˈneɪʃən/]

n. 层间

英英释义

单词用法

同义词

反义词

例句

1.Furthermore, it indicates that it is suitable to analyse the ultimate load of a cross-ply laminated short beam with the measured shear strength of cross-interlamination.

文末还说明了，利用测定的正交层间剪切强度来分析正交铺设层合板短梁的极限载荷是合适的。

2.Furthermore, it indicates that it is suitable to analyse the ultimate load of a cross-ply laminated short beam with the measured shear strength of cross-interlamination.

文末还说明了，利用测定的正交层间剪切强度来分析正交铺设层合板短梁的极限载荷是合适的。

3.The process of interlamination involves layering different materials to enhance strength and durability.

层间叠加的过程涉及将不同材料分层以增强强度和耐用性。

4.In the production of laminated wood, interlamination is crucial for achieving the desired structural integrity.

在胶合木的生产中，层间叠加对实现所需的结构完整性至关重要。

5.The interlamination of metals can create composite materials with unique properties.

层间叠加金属可以创造出具有独特性能的复合材料。

6.Architects often use interlamination techniques to design buildings that are both aesthetic and functional.

建筑师常常使用层间叠加技术来设计既美观又实用的建筑。

7.The study focused on the effects of interlamination on the thermal insulation properties of the material.

该研究集中于层间叠加对材料热绝缘性能的影响。

作文

In the world of materials science and engineering, the concept of interlamination plays a crucial role in the development of composite materials. The process of interlamination refers to the layering of different materials together to form a composite that possesses unique properties not found in the individual components. This technique is widely used in various industries, including aerospace, automotive, and construction, where the need for lightweight yet strong materials is paramount.Composite materials created through interlamination often exhibit enhanced strength, durability, and resistance to environmental factors. For example, in aerospace applications, engineers utilize interlamination to create lightweight structures that can withstand extreme conditions while maintaining structural integrity. The layering of materials such as carbon fiber and epoxy resin results in a composite that is not only lighter than traditional metals but also offers superior performance in terms of fuel efficiency and overall safety.The process of interlamination involves careful consideration of the properties of each layer. Different materials can be combined to achieve specific characteristics, such as flexibility, thermal resistance, or electrical conductivity. In the automotive industry, interlamination is employed to produce parts that are both lightweight and capable of absorbing impact energy, thereby enhancing vehicle safety without compromising performance.Moreover, interlamination can also contribute to sustainability efforts in manufacturing. By combining recycled materials with new ones, manufacturers can create composites that reduce waste and lower the environmental impact of production processes. This approach aligns with the increasing demand for eco-friendly solutions in various sectors and showcases the versatility of interlamination techniques.In construction, the use of interlamination has revolutionized the way buildings are designed and constructed. Laminated timber, for instance, is a product of interlamination that allows for the creation of large structural elements that are both aesthetically pleasing and structurally sound. This method not only enhances the strength of wood but also minimizes the risk of warping or cracking, making it a preferred choice for modern architectural designs.Despite its numerous advantages, the process of interlamination is not without challenges. Engineers must carefully manage the bonding between layers to ensure that the composite material performs as intended. Any defects in the interlamination process can lead to weaknesses in the final product, which may compromise safety and performance. Therefore, rigorous testing and quality control measures are essential to ensure the reliability of laminated composites.In conclusion, interlamination is a vital process in the creation of advanced materials that meet the demands of modern industries. Its ability to combine different materials into a single, high-performance composite opens up new possibilities in design and application. As technology continues to advance, the role of interlamination will likely expand, leading to even more innovative solutions that enhance the performance and sustainability of materials across various fields.

在材料科学和工程领域，interlamination的概念在复合材料的发展中起着至关重要的作用。interlamination的过程是将不同材料层叠在一起形成一种复合材料，这种复合材料具有单个组件所没有的独特性能。这种技术广泛应用于航空航天、汽车和建筑等多个行业，在这些行业中，轻质而强韧的材料需求至关重要。通过interlamination创造的复合材料通常表现出增强的强度、耐久性和对环境因素的抵抗力。例如，在航空航天应用中，工程师利用interlamination创建能够承受极端条件的轻质结构，同时保持结构完整性。将碳纤维和环氧树脂等材料分层组合，形成的复合材料不仅比传统金属更轻，而且在燃油效率和整体安全性方面提供了卓越的性能。interlamination的过程涉及对每层材料特性的仔细考虑。可以结合不同的材料，以实现特定的特性，例如灵活性、热阻或电导率。在汽车工业中，interlamination被用于生产既轻便又能吸收冲击能量的零部件，从而在不影响性能的情况下提高车辆安全性。此外，interlamination还可以促进制造中的可持续性努力。通过将回收材料与新材料结合，制造商可以创造出减少废物并降低生产过程环境影响的复合材料。这种方法与各个行业日益增长的对环保解决方案的需求相一致，展示了interlamination技术的多样性。在建筑中，interlamination的使用彻底改变了建筑物的设计和建造方式。例如，层压木材就是interlamination的产物，它允许创建既美观又结构坚固的大型结构元素。这种方法不仅增强了木材的强度，还最小化了变形或开裂的风险，使其成为现代建筑设计的首选。尽管有许多优点，interlamination的过程也并非没有挑战。工程师必须仔细管理层之间的粘合，以确保复合材料按预期性能发挥作用。interlamination过程中的任何缺陷都可能导致最终产品的弱点，从而影响安全性和性能。因此，严格的测试和质量控制措施对于确保层压复合材料的可靠性至关重要。总之，interlamination是创建满足现代工业需求的先进材料的重要过程。它将不同材料结合成单一高性能复合材料的能力为设计和应用开辟了新的可能性。随着技术的不断进步，interlamination的角色可能会扩大，从而带来更多创新解决方案，提升各个领域材料的性能和可持续性。