machinability

简明释义

[məˌʃiːnəˈbɪlətɪ][məˌʃiːnəˈbɪləti]

n. 切削性;机械加工性

英英释义

Machinability refers to the ease with which a material can be cut, shaped, or finished using machining processes.

可加工性是指材料在使用机械加工过程中被切割、成型或完成的难易程度。

单词用法

improve machinability

提高可加工性

evaluate machinability

评估可加工性

machinability rating

可加工性评级

material machinability

材料可加工性

machinability testing

可加工性测试

machinability index

可加工性指数

同义词

workability

可加工性

The workability of the material affects the efficiency of the machining process.

材料的可加工性影响加工过程的效率。

fabricability

可制造性

High fabricability is essential for mass production in manufacturing.

高可制造性对于制造中的大规模生产至关重要。

machinableness

可机械加工性

Understanding machinableness helps in selecting the right tools for cutting.

理解可机械加工性有助于选择合适的切削工具。

反义词

unmachinability

不可加工性

The unmachinability of certain materials can lead to increased production costs.

某些材料的不可加工性可能导致生产成本增加。

difficulty in machining

加工困难

High hardness often results in difficulty in machining, requiring special tools.

高硬度通常会导致加工困难,需要特殊工具。

例句

1.The paper presents the machinability of crystal materials, and emphasizes the influence of cutting conditions on the mirror finish.

探讨晶体材料的切削加工性,重点分析切削条件对实现镜面车削的影响。

2.Cold working dies of superior machinability for general use; for large product quenching or wire electronic discharge machining.

切削性优异的通用冷作模具钢。注意大型加工品的淬火及钢丝电火花加工。

3.Hard machinability of hard-brittle material is crucial for its application.

超硬脆材料的难加工性制约了其推广应用。

4.High machinability, particularly suitable for vehicles with small space and limited assembling conditions.

可加工性强,尤其适合空间较小、安装条件有限的车型。

5.Mechanical strength, machinability, surface corrosive and wear abrasion of a new type glass ceramic composed of fluorophlgopite Ca-mice were studied in this article.

研究了一种新型的钙云母为主相高强度的可切削玻璃陶瓷的力学性能、可加工性、表面耐腐蚀性、耐磨耗性。

6.To improve machinability.

增加机械加工性能。

7.Although not used much any more, approximate machinability ratings are available in the example below.

尽管已不再大量的被使用,近乎准确的机加工率在以下的例子中能够被看到。

8.High machinability ratings indicate that a material can be shaped or cut with minimal tool wear.

可加工性评级表示材料可以在最小工具磨损的情况下被成型或切割。

9.The machinability of plastics varies significantly depending on their composition.

塑料的可加工性因其成分而有显著差异。

10.When selecting materials for manufacturing, consider the machinability to ensure efficient production.

在选择制造材料时,要考虑可加工性以确保高效生产。

11.Steel alloys with good machinability are preferred in the automotive industry.

在汽车工业中,具有良好可加工性的钢合金更受欢迎。

12.The machinability of aluminum is often praised for its ease of cutting.

铝的可加工性常因其切削容易而受到赞扬。

作文

Machinability is a term used in manufacturing and engineering that refers to the ease with which a material can be machined to achieve desired dimensions and surface finishes. It is an essential concept in the field of machining, as it directly impacts production efficiency, tool wear, and overall costs. Understanding the machinability of a material can help engineers and machinists select the appropriate tools and processes for their projects. Different materials exhibit varying levels of machinability, which can be influenced by factors such as hardness, toughness, and thermal conductivity. For example, metals like aluminum and brass are known for their excellent machinability, allowing for faster machining speeds and better surface finishes. In contrast, harder materials like titanium and certain stainless steels present challenges due to their lower machinability, often requiring specialized tools and techniques to achieve acceptable results.The importance of machinability extends beyond just the selection of materials. It also plays a crucial role in the design of parts and components. Engineers must consider machinability when designing products to ensure that they can be efficiently manufactured. This involves not only choosing the right materials but also designing features that facilitate machining processes. For instance, avoiding intricate shapes or deep pockets can improve machinability and reduce production time.Moreover, advancements in technology have led to the development of new materials and coatings that enhance machinability. For instance, the introduction of high-speed steel and carbide tools has revolutionized machining practices, allowing for greater precision and efficiency. Additionally, the use of coolant and lubrication during machining processes can significantly improve machinability by reducing friction and heat generation, leading to longer tool life and better surface quality.In conclusion, machinability is a critical factor in the manufacturing process that influences efficiency, cost, and product quality. By understanding the machinability of various materials and considering it in the design phase, engineers and machinists can optimize their workflows and produce high-quality components. As technology continues to evolve, staying informed about the latest developments in machinability will be essential for professionals in the field. Ultimately, a solid grasp of machinability not only enhances productivity but also contributes to the overall success of manufacturing operations.

可加工性是制造和工程领域中的一个术语,指的是材料被加工以达到所需尺寸和表面光洁度的难易程度。它是机械加工领域中的一个重要概念,因为它直接影响生产效率、工具磨损和整体成本。理解材料的可加工性可以帮助工程师和机械师选择适合他们项目的工具和工艺。不同材料表现出不同程度的可加工性,这可能受到硬度、韧性和热导率等因素的影响。例如,铝和黄铜等金属以其优良的可加工性而闻名,允许更快的加工速度和更好的表面光洁度。相比之下,钛和某些不锈钢等较硬材料由于其较低的可加工性而面临挑战,通常需要专门的工具和技术来达到可接受的结果。可加工性的重要性不仅仅体现在材料选择上。它在零件和组件的设计中也起着至关重要的作用。工程师在设计产品时必须考虑可加工性,以确保它们能够高效地制造。这不仅涉及选择合适的材料,还包括设计便于加工的特征。例如,避免复杂的形状或深口可以改善可加工性并减少生产时间。此外,技术的进步导致了新材料和涂层的开发,这些材料和涂层增强了可加工性。例如,高速钢和硬质合金工具的引入彻底改变了加工实践,使得精度和效率大大提高。此外,在加工过程中使用冷却剂和润滑剂可以显著改善可加工性,通过减少摩擦和热量生成,延长工具寿命并改善表面质量。总之,可加工性是制造过程中一个关键因素,影响效率、成本和产品质量。通过理解各种材料的可加工性并在设计阶段考虑这一点,工程师和机械师可以优化他们的工作流程,生产高质量的组件。随着技术的不断发展,保持对最新可加工性发展的了解将对该领域的专业人士至关重要。最终,对可加工性的深入理解不仅提高了生产力,还促进了制造操作的整体成功。