carrier flutter

简明释义

载波颤动

英英释义

例句

1.The engineers conducted tests to measure the impact of carrier flutter on the aircraft's stability.

工程师们进行了测试，以测量载体颤振对飞机稳定性的影响。

2.Engineers use simulations to predict carrier flutter behavior under various conditions.

工程师使用模拟来预测不同条件下的载体颤振行为。

3.During the flight, the pilot noticed a slight carrier flutter that needed immediate attention.

在飞行过程中，飞行员注意到轻微的载体颤振，需要立即处理。

4.The design modifications aimed to reduce carrier flutter in the new model.

设计修改旨在减少新型号中的载体颤振。

5.Understanding carrier flutter is crucial for ensuring passenger safety.

理解载体颤振对确保乘客安全至关重要。

作文

In the realm of aerodynamics and aviation, the term carrier flutter refers to a specific type of oscillation that can occur in aircraft structures, particularly those associated with carrier-based operations. Understanding carrier flutter is crucial for engineers and pilots alike, as it can significantly affect the performance and safety of an aircraft during flight. This phenomenon typically arises when the natural frequency of an aircraft's components aligns with the frequency of external forces acting upon them, such as the turbulent airflow around the wings or the vibrations produced by the engines.When an aircraft is launched from an aircraft carrier, it experiences a unique set of conditions. The rapid acceleration and subsequent deceleration can lead to various mechanical stresses on the aircraft's structure. If these stresses induce vibrations that resonate with the aircraft's natural frequencies, it can result in carrier flutter. This is particularly concerning for carrier-based fighters and bombers, which must operate under these extreme conditions regularly.To mitigate the risks associated with carrier flutter, aerospace engineers conduct extensive testing and simulations during the design phase of an aircraft. They use advanced computational models to predict how different materials and structural designs will respond to various aerodynamic forces. By doing so, they can identify potential flutter issues before the aircraft even takes to the skies. Additionally, real-time monitoring systems are often installed in modern aircraft to detect any signs of flutter during flight, allowing pilots to take corrective action if necessary.The implications of carrier flutter extend beyond just the technical aspects of aircraft design. It also has significant operational considerations. For instance, pilots must be trained to recognize the symptoms of flutter and understand how to respond effectively. This includes adjusting their flight maneuvers and speeds to avoid entering a fluttering condition. Moreover, naval operations require careful planning and coordination to ensure that all aircraft are launched and recovered safely, minimizing the risk of encountering carrier flutter during critical phases of flight.In conclusion, carrier flutter is a complex phenomenon that poses challenges in the field of aviation, particularly for carrier-based aircraft. Its understanding is vital for ensuring the safety and effectiveness of military operations at sea. Through rigorous engineering practices and pilot training, the aviation industry continues to advance its knowledge and techniques to combat this issue, ultimately leading to safer skies for all. The study of carrier flutter not only enhances our understanding of aerodynamics but also highlights the intricate relationship between technology and human skill in the world of aviation.

在空气动力学和航空领域，术语carrier flutter指的是一种特定类型的振荡，可能发生在飞机结构中，尤其是与航母作业相关的部分。理解carrier flutter对工程师和飞行员来说至关重要，因为它能显著影响飞机在飞行中的性能和安全性。这种现象通常发生在飞机组件的固有频率与作用于其上的外力频率（如机翼周围的湍流气流或发动机产生的振动）一致时。当一架飞机从航母上发射时，它会经历一系列独特的条件。快速加速和随后的减速可能导致飞机结构上的各种机械应力。如果这些应力引发的振动与飞机的固有频率共振，就可能导致carrier flutter。这对于基于航母的战斗机和轰炸机尤其令人担忧，因为它们必须在这些极端条件下定期操作。为了减轻与carrier flutter相关的风险，航空工程师在飞机设计阶段进行广泛的测试和模拟。他们使用先进的计算模型来预测不同材料和结构设计如何响应各种空气动力学力。通过这样做，他们可以在飞机首次飞行之前识别潜在的颤振问题。此外，现代飞机通常安装实时监测系统，以在飞行过程中检测任何颤振迹象，从而允许飞行员在必要时采取纠正措施。carrier flutter的影响不仅限于飞机设计的技术方面。它还有显著的操作考虑。例如，飞行员必须接受培训，以识别颤振的症状并了解如何有效应对。这包括调整他们的飞行动作和速度，以避免进入颤振状态。此外，海军行动需要仔细规划和协调，以确保所有飞机安全发射和回收，最大限度地减少在飞行关键阶段遇到carrier flutter的风险。总之，carrier flutter是一个复杂的现象，在航空领域，特别是对于航母上的飞机，带来了挑战。理解这一点对确保海上军事行动的安全和有效性至关重要。通过严格的工程实践和飞行员培训，航空工业不断推进对这一问题的认识和技术，最终为所有人创造了更安全的天空。对carrier flutter的研究不仅提升了我们对空气动力学的理解，也突显了航空世界中技术与人类技能之间的复杂关系。