hydromechanical

简明释义

英[ˌhaɪdrəʊmɪˈkænɪkl]美[ˌhaɪdroʊməˈkænɪkl]

adj. 流体力学的

英英释义

单词用法

同义词

反义词

例句

1.The hydromechanical principle was used to determine the tank structure reasonably in design. The aims of increasing sediment ability and satisfying technology index were realized.

在设计中利用流体力学的诸多原理，合理地确定槽体结构，到达了进步沉降能力，满足生产工艺指标要求的目的。

2.The hydromechanical principle was used to determine the tank structure reasonably in design. The aims of increasing sediment ability and satisfying technology index were realized.

在设计中利用流体力学的诸多原理，合理地确定槽体结构，到达了进步沉降能力，满足生产工艺指标要求的目的。

3.Hydromechanical transmission, four-wheel drive offer larger driving force and breakout force: light and flexible small turning radius is particularly suitable for limited field.

采用液力机械传动、四轮驱动，具备较大的驱动力和掘起力：转弯半径小，轻便灵活，尤其适合狭窄场地作业。

4.The hydromechanical continuous variable transmission is a new kind transmission, in which the automatic shift could be achieved by the electronic control system.

液压机械无级变速传动可以通过电控系统实现自动换挡。

5.According to theoretic analysis, traditional definition of combined swirl strength cannot sufficiently reflect the hydromechanical rule of combined swirl jets.

通过理论分析表明，传统的组合旋流强度定义不能充分体现组合旋流的流体动力学规律。

6.The theory basis of optimization design, parameters matching and performance analysis of hydromechanical differential turning system are provided.

从而为液压机械差速转向系统的优化设计、参数匹配及性能分析提供理论依据。

7.Conical degree spiral packing has unique structure, and has completely different hydromechanical characteristics with the conventional packing.

锥度螺旋填料独特的结构，使其具有与常规填料完全不同的流体力学特性。

8.The shock absorber system works by purely hydromechanical means without the need for sensors or electronics.

减振器系统纯粹基于流体力学原理工作，不需要任何的传感器或电子装置。

9.Hydromechanical coupling of jointed rock mass was the key point for problems of hydraulics of rock mass.

裂隙岩体的渗流应力耦合机理是岩体水力学的研究重点。

10.A systematic approach to the design of a three-shaft hydromechanical transmission (HMT) is proposed.

推荐了一个系统的方法用于设计三轴线液力机械变速器(HMT)。

11.The new design of the dam incorporates advanced hydromechanical 水力机械的 systems to optimize water flow.

新设计的大坝结合了先进的水力机械的系统，以优化水流。

12.Engineers are studying the hydromechanical 水力机械的 properties of the river to improve flood management.

工程师们正在研究河流的水力机械的特性，以改善洪水管理。

13.The hydromechanical 水力机械的 actuator allows for precise control of the hydraulic system.

该水力机械的执行器允许对液压系统进行精确控制。

14.In marine engineering, hydromechanical 水力机械的 systems are crucial for the operation of submarines.

在海洋工程中，水力机械的系统对于潜艇的操作至关重要。

15.The research focused on the hydromechanical 水力机械的 interactions between different fluid types.

研究集中在不同流体类型之间的水力机械的相互作用上。

作文

In recent years, the field of engineering has seen significant advancements, particularly in the areas of fluid dynamics and mechanical systems. One term that has gained prominence in this context is hydromechanical, which refers to the interaction between hydraulic fluids and mechanical components. Understanding this concept is crucial for engineers working on various applications, from automotive systems to aerospace technology. The hydromechanical systems utilize the principles of fluid mechanics to transmit power and control movement. For example, in hydraulic brakes, the force applied to the brake pedal is transmitted through hydraulic fluid to the brake pads, allowing for effective stopping power. This system exemplifies how hydromechanical principles are applied in everyday vehicles, enhancing safety and performance. Moreover, hydromechanical systems are not limited to automotive applications. In the aerospace industry, these systems play a vital role in the operation of flight control mechanisms. Aircraft rely on hydraulic systems to manage flaps, landing gear, and other critical functions. The efficiency of these hydromechanical systems can greatly impact the overall performance and safety of the aircraft. In addition to transportation, hydromechanical engineering is also pivotal in the design of various industrial machinery. For instance, construction equipment such as excavators and bulldozers heavily depend on hydraulic systems for their operation. The ability to lift heavy loads and perform precise movements is made possible through the effective use of hydromechanical principles. Furthermore, the integration of advanced technologies, such as sensors and automation, into hydromechanical systems has opened new avenues for innovation. Smart hydraulic systems can adjust their performance based on real-time data, improving efficiency and reducing energy consumption. This evolution reflects the ongoing trend towards sustainability in engineering practices. Despite the advantages of hydromechanical systems, there are challenges that engineers must address. Issues such as fluid leakage, maintenance requirements, and potential failure modes must be carefully considered during the design phase. Engineers are continually researching ways to enhance the reliability and longevity of these systems, ensuring they can withstand the demands of modern applications. In conclusion, the term hydromechanical encapsulates a vital area of study within engineering that focuses on the interplay between fluids and mechanical systems. Its applications span various industries, including automotive, aerospace, and construction. As technology continues to advance, the importance of understanding hydromechanical principles will only grow, paving the way for more efficient and innovative solutions in engineering. By mastering this concept, engineers can contribute to the development of safer, more reliable systems that enhance our daily lives. In summary, hydromechanical (水力机械的) systems are integral to numerous engineering applications, emphasizing the significance of fluid dynamics in mechanical design and operation. As we move forward, the continuous exploration of hydromechanical technologies will undoubtedly lead to breakthroughs that improve functionality and sustainability across various sectors.

近年来，工程领域取得了显著进展，特别是在流体动力学和机械系统方面。一个在这个背景下逐渐受到关注的术语是hydromechanical，它指的是液压流体与机械组件之间的相互作用。理解这个概念对从事各种应用的工程师至关重要，从汽车系统到航空航天技术。 hydromechanical系统利用流体力学的原理来传递动力和控制运动。例如，在液压刹车中，施加在刹车踏板上的力量通过液压流体传递到刹车片，从而实现有效的制动。这一系统展示了hydromechanical原理在日常车辆中的应用，增强了安全性和性能。 此外，hydromechanical系统不仅限于汽车应用。在航空航天工业中，这些系统在飞行控制机制的操作中发挥着至关重要的作用。飞机依赖于液压系统来管理襟翼、起落架和其他关键功能。这些hydromechanical系统的效率可以极大地影响飞机的整体性能和安全性。 除了交通运输，hydromechanical工程在各种工业机械的设计中也具有重要意义。例如，挖掘机和推土机等建筑设备在其操作中严重依赖液压系统。提升重物和执行精确动作的能力是通过有效使用hydromechanical原理实现的。 此外，将先进技术（如传感器和自动化）集成到hydromechanical系统中，为创新开辟了新途径。智能液压系统可以根据实时数据调整其性能，提高效率并减少能源消耗。这一演变反映了工程实践中可持续发展的持续趋势。 尽管hydromechanical系统具有诸多优势，但工程师必须解决一些挑战。在设计阶段，液体泄漏、维护要求和潜在故障模式等问题必须得到仔细考虑。工程师们正在不断研究如何提高这些系统的可靠性和耐久性，以确保它们能够承受现代应用的需求。 总之，术语hydromechanical概括了工程学中的一个重要研究领域，专注于流体与机械系统之间的相互作用。它的应用遍及汽车、航空航天和建筑等多个行业。随着技术的不断进步，理解hydromechanical原理的重要性只会增加，为工程中的更高效和创新的解决方案铺平道路。通过掌握这一概念，工程师可以为开发更安全、更可靠的系统做出贡献，提升我们的日常生活。 总之，hydromechanical（水力机械的）系统是众多工程应用中不可或缺的一部分，强调了流体动力学在机械设计和操作中的重要性。随着我们向前发展，对hydromechanical技术的持续探索无疑将导致突破，改善各个领域的功能和可持续性。