fabrication property

简明释义

加工性能

英英释义

例句

1.Before selecting a material, it's crucial to analyze its fabrication properties to ensure it meets project requirements.

在选择材料之前，分析其制造特性以确保符合项目要求至关重要。

2.The fabrication properties of composites can vary significantly depending on the manufacturing technique used.

复合材料的制造特性可能会因所使用的制造技术而显著不同。

3.The engineer emphasized the importance of understanding the fabrication property in order to optimize the manufacturing process.

工程师强调理解制造特性的重要性，以优化生产过程。

4.Understanding the fabrication property of a metal can help predict how it will behave under stress.

理解金属的制造特性可以帮助预测其在应力下的表现。

5.Different materials have unique fabrication properties that affect their usability in construction.

不同材料具有独特的制造特性，这会影响它们在建筑中的可用性。

作文

In the field of materials science and engineering, the term fabrication property refers to the characteristics that influence how a material can be processed and shaped into desired forms. These properties are crucial for manufacturers and engineers as they determine the feasibility of producing components in various industries, from automotive to aerospace. Understanding fabrication property is essential for optimizing production processes and ensuring the quality of the final products.One of the primary aspects of fabrication property is the material's workability, which describes how easily a material can be manipulated without breaking or losing its structural integrity. For instance, metals like aluminum possess excellent workability, allowing them to be easily extruded, rolled, or stamped into complex shapes. This characteristic makes them ideal for applications where lightweight and strength are required, such as in aircraft manufacturing.Another important factor related to fabrication property is the material's thermal properties. Materials with high thermal conductivity can be easily welded or soldered, making them suitable for applications that require joining different parts together. Conversely, materials with low thermal conductivity may require special techniques to ensure proper bonding during fabrication. For example, thermoplastics have relatively low thermal conductivity and often need additional methods like adhesives or mechanical fasteners to join components effectively.Moreover, the fabrication property also encompasses the material's response to various fabrication techniques. Some materials may respond well to traditional manufacturing processes, while others may require advanced techniques such as additive manufacturing or 3D printing. For instance, polymers can often be molded into intricate shapes using injection molding, whereas metals might be better suited for machining or casting.The choice of material based on its fabrication property can significantly impact the overall cost and efficiency of the production process. Engineers must consider not only the performance characteristics of the material but also how it will be fabricated. For example, selecting a material that is difficult to machine may lead to higher labor costs and longer production times. Therefore, understanding the fabrication property helps in making informed decisions that balance performance, cost, and manufacturability.In conclusion, the concept of fabrication property plays a vital role in the selection and processing of materials in various industries. By understanding the workability, thermal properties, and responses to different fabrication techniques, engineers can optimize their manufacturing processes and improve the quality of their products. As technology continues to advance, the importance of comprehending fabrication property will only grow, paving the way for innovative solutions in material design and manufacturing practices.

在材料科学和工程领域，术语fabrication property指的是影响材料如何被加工和成型为所需形状的特性。这些特性对制造商和工程师至关重要，因为它们决定了在汽车、航空航天等各个行业生产组件的可行性。理解fabrication property对于优化生产过程和确保最终产品的质量至关重要。fabrication property的一个主要方面是材料的可加工性，它描述了材料在不破裂或失去结构完整性的情况下被操纵的难易程度。例如，铝等金属具有优良的可加工性，使其能够轻松地被挤压、轧制或冲压成复杂形状。这一特性使得它们非常适合用于需要轻量和强度的应用，例如飞机制造。与fabrication property相关的另一个重要因素是材料的热性能。具有高热导率的材料可以很容易地焊接或钎焊，使其适合于需要将不同部件连接在一起的应用。相反，具有低热导率的材料可能需要特殊技术以确保在制造过程中正确粘合。例如，热塑性塑料的热导率相对较低，通常需要附加的方法，如粘合剂或机械紧固件来有效连接组件。此外，fabrication property还包括材料对各种制造技术的响应。有些材料可能对传统制造工艺反应良好，而其他材料可能需要先进的技术，如增材制造或3D打印。例如，聚合物通常可以通过注塑成型成复杂形状，而金属可能更适合于机械加工或铸造。根据其fabrication property选择材料会显著影响生产过程的整体成本和效率。工程师必须考虑材料的性能特性以及它将如何被加工。例如，选择一种难以加工的材料可能导致更高的人工成本和更长的生产时间。因此，理解fabrication property有助于做出平衡性能、成本和可制造性的明智决策。总之，fabrication property的概念在各个行业的材料选择和加工中发挥着至关重要的作用。通过理解可加工性、热性能以及对不同制造技术的响应，工程师可以优化其制造过程，提高产品质量。随着技术的不断进步，理解fabrication property的重要性只会增加，为材料设计和制造实践中的创新解决方案铺平道路。