aerodynamical 英['eəroʊdɪnɪmɪk(ə)l] 美['erəʊdɪnɪmɪkəl]
发音:/eˈroʊdɪnɪmɪkəl/
意思:有关空气动力学的
用法:通常在名词前作定语,表示某事物的性质或特征。
记忆方法:aero(空气) + dynami(动力) + cal(形容词词尾) = 空气动力学的。
aerodynamical的发音音标/eəroʊdɪnɪmɪk(ə)l/,发音时,/e/的发音嘴形要半开,舌端靠近下齿,声带不振动;/r/发音时,舌尖后缩,舌前部抬高,靠近上颚;/dɪnɪmɪk/是单词dynamic的复数形式,表示动力、力的作用;/l/是音标后一个辅音。
aerodynamical的用法和意思:表示与空气动力学相关的,通常用于描述与飞机、飞行器等与空气动力学相关的性质或特征。
aerodynamical发音为/eəroʊdɪnɪmɪk(ə)l/,意思为有关空气动力学的。可以记住这个单词的方法是将aero(空气)和dynami(动力)结合起来,想象一下在空气中有很多动力在作用,从而记住这个单词。
分别的发音是[bi'viːn],分别的用法可以表示不同的人或事物,也可以表示不同的时间或地点。分别可以用作形容词、副词、名词。分别怎么记可以结合不同的场景来记,例如分别可以和“离别”、“再见”等场景结合来记。
aerodynamical是流体力学相关的物理现象。它主要研究气体或液体的流动特性,以及物体在气体或液体中运动时的受力情况。具体来说,aerodynamical现象包括:
1. 伯努利定律:流速大的地方流体静压力小,流速小的地方流体静压力大。
2. 流体流动时的压强分布规律:流体在管道中平流时,同一水平面上的压强都相等,且气体的压强随流速的增大而增大。
3. 流体流动时产生漩涡,当流体绕流物体时,物体会刺激流体的流动状态发生变化,从而在物体的周围产生旋涡。
因此,aerodynamical涉及到的物理现象是非常广泛的,包括力学、热学、电学等多个领域。这些现象在现实生活中有着广泛的应用,如飞机飞行、汽车行驶、河流漩涡等等。
Aerodynamical Management: The Key to Success in the Aviation Industry
Aerodynamical management is a crucial aspect of aviation that has a significant impact on the success of an airline or aviation company. It involves the use of aerodynamics principles to optimize flight operations, reduce fuel consumption, and improve safety. In this article, we will explore the importance of aerodynamical management and how it can be applied in the aviation industry.
Firstly, aerodynamic principles are essential for optimizing flight operations. Understanding the forces acting on an aircraft during flight, such as lift, drag, and thrust, allows for the design and optimization of flight paths, aircraft configurations, and propulsion systems. By using these principles, airlines can reduce fuel consumption and increase efficiency, resulting in cost savings and increased profits.
Secondly, aerodynamic management can help reduce environmental impact. With the increasing concerns about climate change and sustainability, airlines need to take measures to reduce their carbon footprint. Aerodynamic management can help airlines achieve this by reducing fuel consumption, which in turn reduces greenhouse gas emissions.
Thirdly, aerodynamic management can improve safety by reducing air turbulence and enhancing flight stability. Using aerodynamics to design smoother flight paths and more stable aircraft configurations can reduce the risk of accidents and enhance passenger comfort.
To achieve these goals, airlines need to implement a comprehensive aerodynamical management strategy that includes training and education for flight crews and engineers, as well as the use of advanced technology and equipment. Additionally, airlines should collaborate with other aviation stakeholders to share knowledge and best practices, and work towards developing a sustainable aviation industry.
In conclusion, aerodynamical management is essential for the success of aviation companies. By optimizing flight operations, reducing fuel consumption, and enhancing safety, airlines can achieve cost savings, increased profits, and a positive impact on the environment. To achieve these goals, airlines need to implement a comprehensive aerodynamical management strategy that includes training and education, advanced technology and equipment, and collaboration with other aviation stakeholders.
In the future, we expect to see more advancements in aerodynamic technology and equipment that will further improve flight operations and reduce environmental impact. Additionally, we believe that aerodynamical management will become increasingly important as airlines strive to meet the demands of a growing global aviation market while maintaining safety and sustainability standards.