machining dimension

简明释义

机械加工尺寸

英英释义

例句

1.We need to review the machining dimension 加工尺寸 in the technical drawing before proceeding.

在继续之前，我们需要审查技术图纸中的machining dimension 加工尺寸。

2.The CNC machine operator adjusted the settings to achieve the desired machining dimension 加工尺寸.

数控机床操作员调整了设置以达到所需的machining dimension 加工尺寸。

3.It's crucial to maintain the correct machining dimension 加工尺寸 to avoid assembly issues later.

保持正确的machining dimension 加工尺寸是避免后期组装问题的关键。

4.The engineer specified the machining dimension 加工尺寸 for the part to ensure it fits properly.

工程师指定了该零件的machining dimension 加工尺寸以确保其适配良好。

5.During the quality control process, we measured the machining dimension 加工尺寸 to verify compliance with the specifications.

在质量控制过程中，我们测量了machining dimension 加工尺寸以验证其是否符合规格。

作文

In the realm of manufacturing and engineering, precision is paramount. One key aspect that ensures the quality and functionality of manufactured parts is the concept of machining dimension. The term machining dimension refers to the specific measurements and tolerances that are applied during the machining process to achieve the desired shape and size of a component. Understanding machining dimension is crucial for engineers and machinists alike, as it directly impacts the fit, performance, and durability of the final product.When we talk about machining dimension, we are essentially discussing the numerical values that define how a part should be fabricated. This includes not only the overall dimensions such as length, width, and height but also the intricate details like hole diameters, surface finishes, and angular relationships. Each of these factors plays a significant role in ensuring that the part meets its intended purpose.For instance, in the automotive industry, a slight deviation in the machining dimension of engine components can lead to catastrophic failures. If a cylinder head is machined incorrectly, it may not seal properly, resulting in loss of compression and ultimately affecting the engine's performance. Therefore, strict adherence to machining dimension specifications is imperative in such high-stakes environments.Moreover, the importance of machining dimension extends beyond just the physical characteristics of a part. It also encompasses the processes used to achieve these dimensions. Different machining techniques, such as milling, turning, and grinding, have their own capabilities and limitations regarding the precision they can achieve. For example, CNC (Computer Numerical Control) machining allows for incredibly precise machining dimension specifications to be met consistently, which is essential for modern manufacturing practices.In addition to the technical aspects, understanding machining dimension also involves a comprehension of the standards and regulations that govern the industry. Organizations such as the International Organization for Standardization (ISO) provide guidelines on acceptable tolerances and measurement methods, which help ensure that all manufacturers are held to the same high standards. This standardization is vital for maintaining quality across different suppliers and manufacturers, especially in industries where components are sourced from multiple locations.As technology continues to advance, the role of machining dimension in manufacturing will likely evolve as well. The integration of smart technologies and automation into the machining process can enhance the ability to monitor and control machining dimension in real-time, leading to even greater precision and efficiency. Furthermore, the rise of additive manufacturing, or 3D printing, introduces new challenges and considerations regarding machining dimension, as the processes involved differ significantly from traditional machining methods.In conclusion, the concept of machining dimension is a fundamental element of the manufacturing process that cannot be overlooked. It encompasses the precise measurements and tolerances necessary for creating functional and reliable components. A thorough understanding of machining dimension is essential for professionals in the field, as it influences not only the quality of the products but also the safety and efficiency of the systems they are a part of. As the industry continues to innovate, staying informed about machining dimension will be crucial for anyone involved in manufacturing and engineering.

在制造和工程领域，精确性至关重要。确保制造零件质量和功能的一个关键方面是“machining dimension”的概念。术语“machining dimension”指的是在加工过程中应用于实现组件所需形状和尺寸的特定测量和公差。理解“machining dimension”对工程师和机械师来说至关重要，因为它直接影响最终产品的配合、性能和耐用性。当我们谈论“machining dimension”时，我们实际上是在讨论定义零件应如何制造的数值。这不仅包括整体尺寸，如长度、宽度和高度，还包括孔径、表面光洁度和角度关系等复杂细节。这些因素在确保零件满足其预期用途方面发挥着重要作用。例如，在汽车工业中，发动机部件的“machining dimension”稍有偏差可能导致灾难性的故障。如果气缸盖加工不当，可能无法正确密封，导致压缩损失，最终影响发动机的性能。因此，在这种高风险环境中，严格遵守“machining dimension”规格是至关重要的。此外，“machining dimension”的重要性不仅限于零件的物理特征。它还包括用于实现这些尺寸的过程。不同的加工技术，如铣削、车削和磨削，在它们能够达到的精度方面各有其能力和局限性。例如，CNC（计算机数控）加工可以一致地满足非常精确的“machining dimension”规格，这对于现代制造实践至关重要。除了技术方面，理解“machining dimension”还涉及对行业规范和法规的理解。国际标准化组织（ISO）等组织提供关于可接受公差和测量方法的指导，帮助确保所有制造商都遵循相同的高标准。这种标准化对于在多个供应商和制造商之间保持质量至关重要，特别是在组件来自多个地点的行业中。随着技术的不断进步，“machining dimension”在制造中的角色也可能会发展。将智能技术和自动化集成到加工过程中，可以增强实时监控和控制“machining dimension”的能力，从而实现更大的精度和效率。此外，增材制造或3D打印的兴起也带来了关于“machining dimension”的新挑战和考虑，因为所涉及的过程与传统加工方法显著不同。总之，“machining dimension”的概念是制造过程中不可忽视的基本要素。它包含了创建功能性和可靠组件所需的精确测量和公差。对专业人士而言，深入理解“machining dimension”至关重要，因为它不仅影响产品的质量，还影响它们所处系统的安全性和效率。随着行业的不断创新，了解“machining dimension”将对任何参与制造和工程的人至关重要。