burst point air density

简明释义

爆炸点空气密度

英英释义

例句

1.Engine efficiency can be optimized by understanding the burst point air density (爆破点空气密度) at various altitudes.

通过了解不同高度的爆破点空气密度（burst point air density）可以优化发动机效率。

2.During testing, the engineers measured the burst point air density (爆破点空气密度) to ensure safety standards were met.

在测试过程中，工程师测量了爆破点空气密度（burst point air density），以确保符合安全标准。

3.Pilots must consider the burst point air density (爆破点空气密度) when planning their flight routes.

飞行员在规划航线时必须考虑爆破点空气密度（burst point air density）。

4.Meteorologists use the burst point air density (爆破点空气密度) to predict weather patterns and turbulence.

气象学家使用爆破点空气密度（burst point air density）来预测天气模式和湍流。

5.The aircraft's performance is heavily influenced by the burst point air density (爆破点空气密度), especially during takeoff.

飞机的性能受到爆破点空气密度（burst point air density）的严重影响，特别是在起飞时。

作文

Understanding the concept of burst point air density is crucial in various fields, particularly in aerodynamics and engineering. The term refers to the specific air density at which a material or structure, such as a balloon or an aircraft, can no longer withstand the internal pressure and ultimately fails or bursts. This phenomenon is not only fascinating but also essential for ensuring safety and efficiency in design processes.When we talk about burst point air density in relation to balloons, for instance, it is important to consider how temperature and altitude affect air density. As altitude increases, the air becomes less dense, which means that the internal pressure of a balloon must be carefully monitored. If the external air density drops too low, the balloon could expand excessively due to the internal pressure, leading to a potential burst. Understanding this relationship helps engineers create balloons that can operate safely at various altitudes.In aviation, the significance of burst point air density becomes even more pronounced. Aircraft are designed with specific materials that can withstand certain pressures. However, if the air density changes significantly during flight, it can lead to structural failures. For example, during a rapid ascent or descent, the aircraft may experience changes in air density that could compromise its integrity if not properly accounted for in the design process. Thus, engineers must calculate the burst point air density to ensure that the aircraft can handle these changes without risk of failure.Moreover, the burst point air density is also relevant in the field of meteorology. Weather balloons, which are used to collect data about the atmosphere, rely on accurate predictions of air density to function effectively. If the air density at a certain altitude is not correctly anticipated, the balloon may burst prematurely, resulting in lost data and resources. Meteorologists must understand the implications of burst point air density when designing experiments and interpreting results.In summary, the term burst point air density encompasses a critical aspect of material science and engineering. It serves as a reminder of the delicate balance between pressure and density, which is fundamental in various applications, from aerospace to meteorology. By grasping the importance of this concept, professionals can enhance safety measures and improve the performance of their designs. The interplay between pressure, temperature, and air density is an intricate dance that engineers and scientists must navigate to prevent catastrophic failures. Therefore, understanding burst point air density is not just an academic exercise; it is a vital component of practical application in many fields.

理解“burst point air density”的概念在各个领域中至关重要，特别是在空气动力学和工程学中。这个术语指的是一种特定的空气密度，在这种密度下，材料或结构（如气球或飞机）无法再承受内部压力，最终导致其破裂或爆炸。这种现象不仅令人着迷，而且对于确保设计过程中的安全性和效率至关重要。当我们谈论与气球相关的“burst point air density”时，考虑温度和高度如何影响空气密度是非常重要的。随着高度的增加，空气变得稀薄，这意味着气球的内部压力必须得到仔细监控。如果外部空气密度降得太低，气球可能会由于内部压力而过度膨胀，导致潜在的破裂。理解这种关系有助于工程师制造能够在不同高度安全操作的气球。在航空领域，“burst point air density”的重要性更加明显。飞机的设计采用特定材料，可以承受一定的压力。然而，如果飞行过程中空气密度发生显著变化，可能会导致结构故障。例如，在快速上升或下降过程中，飞机可能会经历空气密度的变化，如果在设计过程中未能妥善考虑这些变化，则可能会危及其完整性。因此，工程师必须计算“burst point air density”，以确保飞机能够处理这些变化而不出现故障风险。此外，“burst point air density”在气象学领域也很重要。气象气球用于收集大气数据，依赖于对空气密度的准确预测。如果在某一高度的空气密度未能正确预估，气球可能会过早破裂，导致数据和资源的损失。气象学家必须理解“burst point air density”的含义，以便在设计实验和解释结果时做出明智的决策。总之，“burst point air density”这一术语涵盖了材料科学和工程学中的一个关键方面。它提醒我们压力和密度之间微妙的平衡，这在多个应用中都是基础，从航空航天到气象学。通过掌握这一概念的重要性，专业人士可以增强安全措施并改善设计性能。压力、温度和空气密度之间的相互作用是一场复杂的舞蹈，工程师和科学家必须在其中找到平衡，以防止灾难性的故障。因此，理解“burst point air density”不仅仅是学术练习；它是许多领域实践应用的重要组成部分。