controlling depth
简明释义
可航最小水深
英英释义
The depth at which a particular operation or process is managed or regulated to ensure optimal performance and safety. | 管理或调节特定操作或过程的深度,以确保最佳性能和安全性。 |
例句
1.In fishing, knowing the controlling depth 控制深度 of the target species can significantly improve catch rates.
在捕鱼时,了解目标物种的控制深度 controlling depth可以显著提高捕获率。
2.During dredging operations, workers monitor the controlling depth 控制深度 to ensure the waterway remains navigable.
在疏浚作业中,工人监测控制深度 controlling depth以确保水道可通行。
3.In underwater construction, engineers must ensure the controlling depth 控制深度 is maintained to avoid structural damage.
在水下施工中,工程师必须确保保持控制深度 controlling depth以避免结构损坏。
4.The pilot adjusted the vessel's ballast to achieve the desired controlling depth 控制深度 for safe navigation.
飞行员调整了船只的压载,以达到安全航行所需的控制深度 controlling depth。
5.The geologist studied the sediment layers at the controlling depth 控制深度 to gather information about past environmental conditions.
地质学家研究控制深度 controlling depth处的沉积层,以收集有关过去环境条件的信息。
作文
In the realm of engineering and design, the term controlling depth refers to the maximum extent to which a particular element can be submerged or embedded in a medium without compromising its integrity or functionality. This concept is crucial in various fields, including civil engineering, architecture, and underwater construction. Understanding the controlling depth is essential for ensuring safety and durability in structures that interact with water or other fluids.For instance, when designing a bridge, engineers must consider the controlling depth of the water beneath it. If the bridge piers are not anchored deep enough, they may be at risk of being undermined by erosion or scouring caused by flowing water. Therefore, determining the appropriate controlling depth is vital for the stability of the bridge, especially during periods of heavy rainfall or flooding.Similarly, in underwater construction projects, such as the installation of pipelines or foundations for offshore platforms, the controlling depth plays a significant role. Engineers must assess the seabed conditions, including soil type and hydrodynamic forces, to establish the optimum depth for laying these structures. A miscalculation could lead to catastrophic failures, resulting in costly repairs and environmental hazards.Moreover, the controlling depth is not limited to physical structures; it also applies to various scientific and technological applications. For example, in the field of oceanography, researchers often study marine life at different depths of the ocean. The controlling depth in this context might refer to the maximum depth at which certain species can thrive, influenced by factors such as light availability, pressure, and temperature. Understanding these limits is crucial for conservation efforts and managing marine ecosystems.In agriculture, the controlling depth can refer to the depth at which crops' roots can effectively absorb nutrients and water. Farmers must understand the controlling depth to optimize planting techniques and irrigation strategies, ensuring healthy crop growth and sustainable farming practices. By monitoring soil conditions and root development, they can adjust their methods to enhance productivity while minimizing environmental impact.In summary, the concept of controlling depth transcends various disciplines, emphasizing the importance of depth management in engineering, science, and agriculture. Whether it's ensuring the stability of a bridge, the successful installation of underwater structures, the study of marine ecosystems, or optimizing agricultural practices, understanding and applying the principles of controlling depth is essential. As we continue to innovate and explore new frontiers, the significance of this concept will undoubtedly grow, highlighting the need for careful consideration of depth in our designs and practices. Thus, mastering the idea of controlling depth is not just an academic exercise; it is a practical necessity that impacts our safety, sustainability, and efficiency across multiple domains.
在工程和设计领域,术语controlling depth指的是一个特定元素可以在不损害其完整性或功能性的情况下被淹没或嵌入介质的最大深度。这个概念在土木工程、建筑和水下施工等多个领域中至关重要。理解controlling depth对于确保与水或其他流体相互作用的结构的安全性和耐久性至关重要。例如,在设计桥梁时,工程师必须考虑桥下水面的controlling depth。如果桥墩的锚固深度不足,可能会因水流造成的侵蚀或冲刷而面临被削弱的风险。因此,确定合适的controlling depth对于桥梁的稳定性至关重要,特别是在暴雨或洪水期间。同样,在水下施工项目中,如管道的安装或海上平台基础的建设,controlling depth也起着重要作用。工程师必须评估海床条件,包括土壤类型和水动力力,以确定铺设这些结构的最佳深度。错误的计算可能导致灾难性的失败,造成昂贵的修复费用和环境危害。此外,controlling depth不仅限于物理结构,它还适用于各种科学和技术应用。例如,在海洋学领域,研究人员经常研究海洋不同深度的生物。此上下文中的controlling depth可能指的是某些物种能够繁衍生息的最大深度,这受到光照可用性、压力和温度等因素的影响。理解这些限制对于保护工作和管理海洋生态系统至关重要。在农业中,controlling depth可以指的是作物根系有效吸收养分和水分的深度。农民必须理解controlling depth以优化种植技术和灌溉策略,确保健康的作物生长和可持续的农业实践。通过监测土壤条件和根系发展,他们可以调整方法,以提高生产力,同时最小化对环境的影响。总之,controlling depth的概念跨越了多个学科,强调了在工程、科学和农业中深度管理的重要性。无论是确保桥梁的稳定性,成功安装水下结构,研究海洋生态系统,还是优化农业实践,理解和应用controlling depth的原则都是至关重要的。随着我们不断创新和探索新领域,这一概念的重要性无疑会增长,突显出在我们的设计和实践中仔细考虑深度的必要性。因此,掌握controlling depth的理念不仅仅是学术练习;它是一项实际的必要性,影响着我们在多个领域的安全、可持续性和效率。
相关单词
