pitch helix

简明释义

节距螺旋线

英英释义

例句

1.The pitch helix 螺距螺旋 of a coil spring affects its load-bearing capacity.

线圈弹簧的螺距螺旋 pitch helix 影响其承载能力。

2.In aerospace engineering, understanding the pitch helix 螺距螺旋 of turbine blades is crucial for efficiency.

在航空航天工程中，理解涡轮叶片的螺距螺旋 pitch helix 对于效率至关重要。

3.The design of the screw is based on a specific pitch helix 螺距螺旋 to ensure optimal performance.

螺丝的设计基于特定的螺距螺旋 pitch helix 以确保最佳性能。

4.When creating a 3D model, it's important to accurately define the pitch helix 螺距螺旋 parameters.

在创建3D模型时，准确定义螺距螺旋 pitch helix 参数非常重要。

5.The pitch helix 螺距螺旋 in this gear mechanism allows for smoother operation.

这个齿轮机制中的螺距螺旋 pitch helix 使操作更加顺畅。

作文

The concept of a pitch helix is integral to understanding various scientific and engineering principles. In simple terms, a pitch helix refers to the geometric arrangement of a helix where the distance between consecutive turns is defined as the pitch. This term is commonly used in the fields of mathematics, physics, and engineering, particularly when discussing the structure of screws, springs, and other helical forms. The pitch of a helix can significantly affect its mechanical properties and functionality. For instance, in the design of a screw, the pitch helix determines how tightly the screw will grip the material it is being driven into. A smaller pitch allows for finer adjustments, while a larger pitch can provide quicker fastening but may compromise grip. Understanding the pitch helix is also crucial in the biological sciences, particularly in the study of DNA. The double helix structure of DNA features a specific pitch that influences how genetic information is stored and replicated. The regularity and consistency of the pitch helix in DNA are vital for the accurate transmission of genetic information from one generation to the next. Any alterations in the pitch can lead to mutations, which can have profound effects on an organism's development and functioning.In engineering, the pitch helix is often analyzed in the context of mechanical systems. For example, in the design of gears and pulleys, the pitch of the helix can affect how power is transmitted through a system. Engineers must carefully calculate the pitch helix to ensure that components work together efficiently and effectively. A well-designed pitch helix can enhance performance and reduce wear and tear on mechanical parts, ultimately leading to longer-lasting machinery.Moreover, the pitch helix has applications in robotics and automation. In robotic arms, the movement of joints is often modeled using helical motions, where the pitch helix plays a critical role in determining the range and precision of motion. By understanding how to manipulate the pitch helix, engineers can create more versatile and capable robotic systems that can perform complex tasks with ease.In conclusion, the pitch helix is a fundamental concept that spans multiple disciplines, from biology to engineering. Its implications are far-reaching, influencing everything from the microscopic structures of DNA to the macroscopic designs of machines. A thorough understanding of the pitch helix not only enhances our grasp of scientific principles but also equips us with the tools necessary to innovate and improve technology in various fields. As we continue to explore the intricacies of the pitch helix, we unlock new possibilities for advancement and discovery in science and engineering.

“螺距螺旋”这一概念对于理解各种科学和工程原理至关重要。简单来说，螺距螺旋是指一个螺旋的几何排列，其中连续圈之间的距离被定义为螺距。这个术语在数学、物理和工程领域中常常被使用，特别是在讨论螺丝、弹簧和其他螺旋形状的结构时。螺旋的螺距会显著影响其机械特性和功能。例如，在螺丝的设计中，螺距螺旋决定了螺丝将如何紧握其被驱入的材料。较小的螺距允许更精细的调整，而较大的螺距则可以提供更快的紧固，但可能会妨碍抓握。理解螺距螺旋在生物科学中同样至关重要，尤其是在DNA研究中。DNA的双螺旋结构具有特定的螺距，这影响着遗传信息的存储和复制。DNA中螺距螺旋的规律性和一致性对于准确地将遗传信息从一代传递到下一代是至关重要的。任何对螺距的改变都可能导致突变，这可能对生物体的发展和功能产生深远影响。在工程学中，螺距螺旋通常在机械系统的背景下进行分析。例如，在齿轮和滑轮的设计中，螺旋的螺距可以影响动力如何在系统中传递。工程师必须仔细计算螺距螺旋以确保各个组件能够高效、有效地协同工作。设计良好的螺距螺旋可以提高性能并减少机械部件的磨损，最终延长机器的使用寿命。此外，螺距螺旋在机器人和自动化中的应用也不容忽视。在机器人手臂中，关节的运动通常使用螺旋运动建模，其中螺距螺旋在确定运动的范围和精度方面起着关键作用。通过理解如何操纵螺距螺旋，工程师可以创造出更灵活、更强大的机器人系统，能够轻松执行复杂的任务。总之，螺距螺旋是一个跨越多个学科的基本概念，从生物学到工程学。它的影响深远，影响着从DNA的微观结构到机器的宏观设计的方方面面。彻底理解螺距螺旋不仅增强了我们对科学原理的掌握，还为我们提供了在各个领域创新和改进技术所需的工具。随着我们继续探索螺距螺旋的复杂性，我们为科学和工程领域的进步和发现开启了新的可能性。