peripheral grinding

简明释义

圆周磨削

英英释义

例句

1.The technician explained that peripheral grinding 周边磨削 is essential for achieving a smooth finish on the edges of the components.

技术员解释说，周边磨削 peripheral grinding 对于实现零件边缘的光滑表面至关重要。

2.The quality control team emphasized the importance of peripheral grinding 周边磨削 in preventing sharp edges that could cause injuries.

质量控制团队强调了周边磨削 peripheral grinding 在防止可能导致伤害的锋利边缘方面的重要性。

3.In our workshop, we use peripheral grinding 周边磨削 to refine the edges of metal parts before assembly.

在我们的车间，我们使用周边磨削 peripheral grinding 来精细加工金属零件的边缘，然后再进行组装。

4.We have invested in advanced machines that specialize in peripheral grinding 周边磨削 to improve production efficiency.

我们已投资于专门从事周边磨削 peripheral grinding 的先进机器，以提高生产效率。

5.Understanding the parameters of peripheral grinding 周边磨削 can significantly enhance the final product quality.

了解周边磨削 peripheral grinding 的参数可以显著提高最终产品的质量。

作文

In the world of manufacturing and engineering, precision is paramount. One of the key processes that ensures this precision is known as peripheral grinding. This technique involves the grinding of the outer edges of a workpiece, allowing for fine-tuning and achieving the desired dimensions and surface finish. Peripheral grinding is particularly crucial in industries where tight tolerances are required, such as aerospace, automotive, and medical device manufacturing.The process begins with the selection of the appropriate grinding wheel, which is determined by the material of the workpiece and the desired finish. The grinding wheel must be hard enough to effectively remove material but also soft enough to avoid damaging the workpiece. Once the right wheel is chosen, the workpiece is secured in place, often using fixtures or clamps, to ensure stability during the grinding operation.During peripheral grinding, the grinding wheel rotates at high speeds, while the workpiece is fed into the wheel at a controlled rate. This combination of speed and feed rate is critical; if either is too high, it could lead to overheating or excessive wear on the wheel. Conversely, if they are too low, the grinding process may become inefficient, resulting in longer cycle times and potentially higher production costs.One of the significant advantages of peripheral grinding is its ability to produce a smooth surface finish and precise dimensions. This is essential for components that will be subjected to high stress or need to fit together with other parts. For example, in the production of gears, the outer edges must be ground accurately to ensure proper meshing with adjacent gears, which directly affects the performance and longevity of the machinery.Moreover, peripheral grinding can be applied to various materials, including metals, plastics, and ceramics. This versatility makes it a valuable process in many different manufacturing environments. Additionally, advancements in technology have led to the development of computer numerical control (CNC) machines that can automate the grinding process, further enhancing precision and efficiency.However, like any manufacturing process, peripheral grinding comes with its challenges. Operators must be well-trained to monitor the grinding operation closely, as issues such as wheel wear, vibration, and thermal damage can affect the quality of the finished product. Regular maintenance of the grinding machines is also essential to ensure consistent performance and to prolong the life of the equipment.In conclusion, peripheral grinding is a vital process in the manufacturing industry that enables the production of high-precision components. Its ability to achieve tight tolerances and excellent surface finishes makes it indispensable in sectors where quality is non-negotiable. As technology continues to evolve, the methods and tools used in peripheral grinding will likely advance, further improving efficiency and effectiveness in manufacturing processes. Understanding and mastering this technique is crucial for anyone involved in precision engineering, as it plays a significant role in the overall success of manufacturing operations.

在制造和工程领域，精确度至关重要。其中一个确保这种精确度的关键过程被称为外周磨削。这种技术涉及对工件外边缘的磨削，从而进行微调并达到所需的尺寸和表面光洁度。外周磨削在需要严格公差的行业中尤为重要，例如航空航天、汽车和医疗设备制造。该过程始于选择适当的磨削轮，这取决于工件的材料和所需的表面处理。磨削轮必须足够坚硬，以有效去除材料，但又不能太软，以免损坏工件。一旦选择了合适的磨削轮，工件就会被固定到位，通常使用夹具或夹具，以确保在磨削操作过程中保持稳定。在外周磨削过程中，磨削轮以高速旋转，而工件以受控速率送入磨削轮。这种速度和进给率的组合至关重要；如果其中任何一个过高，都可能导致过热或磨轮过度磨损。相反，如果它们过低，磨削过程可能会变得低效，导致周期时间延长，可能会增加生产成本。外周磨削的一个显著优势是其能够产生平滑的表面光洁度和精确的尺寸。这对承受高应力或需要与其他部件配合的组件至关重要。例如，在齿轮生产中，外边缘必须准确磨削，以确保与相邻齿轮的正确啮合，这直接影响机械的性能和使用寿命。此外，外周磨削可以应用于多种材料，包括金属、塑料和陶瓷。这种多功能性使其在许多不同的制造环境中成为一种有价值的工艺。此外，技术的进步导致了计算机数控（CNC）机器的发展，可以自动化磨削过程，进一步提高精度和效率。然而，像任何制造过程一样，外周磨削也面临挑战。操作员必须经过良好的培训，以密切监控磨削操作，因为磨轮磨损、振动和热损伤等问题可能会影响成品的质量。定期维护磨削机也是确保一致性能和延长设备使用寿命的关键。总之，外周磨削是制造行业中的一个重要过程，使高精度组件的生产成为可能。其实现严格公差和优良表面光洁度的能力使其在质量不可妥协的行业中不可或缺。随着技术的不断发展，外周磨削中使用的方法和工具可能会进一步改进，提高制造过程的效率和效果。理解和掌握这一技术对于任何参与精密工程的人来说都是至关重要的，因为它在制造操作的整体成功中发挥着重要作用。