quasi propulsive coefficient

简明释义

准推进系数

英英释义

例句

1.The quasi propulsive coefficient 准推进系数 plays a crucial role in determining the overall performance of the spacecraft.

在确定航天器的整体性能时，准推进系数 quasi propulsive coefficient 起着至关重要的作用。

2.By adjusting the fuel flow, we were able to improve the quasi propulsive coefficient 准推进系数 significantly.

通过调整燃料流量，我们能够显著提高准推进系数 quasi propulsive coefficient。

3.In our latest tests, the quasi propulsive coefficient 准推进系数 was found to be higher than expected, indicating a successful design.

在我们最新的测试中，发现准推进系数 quasi propulsive coefficient 高于预期，表明设计成功。

4.The research focused on enhancing the quasi propulsive coefficient 准推进系数 for better energy efficiency in aircraft.

该研究集中在提高准推进系数 quasi propulsive coefficient，以改善飞机的能源效率。

5.The engineer calculated the quasi propulsive coefficient 准推进系数 to optimize the design of the new propulsion system.

工程师计算了准推进系数 quasi propulsive coefficient，以优化新推进系统的设计。

作文

The term quasi propulsive coefficient refers to a measure used in engineering and aerodynamics to assess the efficiency of propulsion systems. In essence, it acts as a comparative indicator that helps engineers evaluate how effectively a propulsion system converts energy into thrust. Understanding this concept is crucial for the design and optimization of various vehicles, including aircraft, rockets, and even automobiles. To comprehend the significance of the quasi propulsive coefficient, one must first grasp the basic principles of propulsion. Propulsion systems work by generating thrust, which is the force that propels an object forward. This thrust can be produced through various means, such as jet engines, rocket engines, or even electric motors. However, not all propulsion systems are created equal; their efficiency can vary widely based on design, fuel type, and operating conditions.The quasi propulsive coefficient provides a standardized way to compare the performance of different propulsion systems under similar conditions. It takes into account factors such as the specific impulse, which measures the efficiency of rocket propellants, and the thrust-to-weight ratio, which indicates how much thrust is generated relative to the weight of the vehicle. By analyzing these parameters, engineers can identify the most effective propulsion strategies for their designs.In practical applications, the quasi propulsive coefficient can be particularly valuable during the development phase of new technologies. For instance, when designing a new aircraft, engineers might test various engine configurations to determine which produces the highest quasi propulsive coefficient. This process involves extensive simulations and real-world testing to gather data on thrust output and fuel consumption.Moreover, the quasi propulsive coefficient can also play a role in improving existing technologies. By analyzing the performance of current propulsion systems, engineers can pinpoint inefficiencies and make necessary adjustments. This could involve altering the design of the engine, changing the type of fuel used, or even implementing advanced materials that reduce weight without sacrificing strength.In conclusion, the quasi propulsive coefficient serves as a vital tool in the field of propulsion engineering. Its ability to quantify the efficiency of propulsion systems enables engineers to make informed decisions during the design and optimization processes. As technology continues to advance, understanding and utilizing the quasi propulsive coefficient will be essential for developing more efficient and effective propulsion systems that meet the demands of modern transportation and exploration. With the ongoing research and innovation in this field, we can expect to see significant improvements in the performance of vehicles powered by various propulsion methods, ultimately leading to a more sustainable and efficient future in transportation.

术语quasi propulsive coefficient指的是工程和空气动力学中用于评估推进系统效率的一个指标。实际上，它充当了一个比较指标，帮助工程师评估推进系统将能量转换为推力的有效性。理解这个概念对于各种交通工具的设计和优化至关重要，包括飞机、火箭甚至汽车。要理解quasi propulsive coefficient的重要性，首先必须掌握推进的基本原理。推进系统通过产生推力来工作，推力是推动物体向前的力量。这种推力可以通过多种方式产生，例如喷气发动机、火箭发动机，甚至电动机。然而，并非所有推进系统都是相同的；它们的效率可能因设计、燃料类型和操作条件而有很大差异。quasi propulsive coefficient提供了一种标准化的方法，可以在类似条件下比较不同推进系统的性能。它考虑了诸如比冲（specific impulse）等因素，比冲衡量火箭推进剂的效率，以及推重比（thrust-to-weight ratio），表示相对于车辆重量产生的推力。通过分析这些参数，工程师可以确定其设计中最有效的推进策略。在实际应用中，quasi propulsive coefficient在新技术开发阶段尤其有价值。例如，在设计新型飞机时，工程师可能会测试各种发动机配置，以确定哪种配置产生最高的quasi propulsive coefficient。这一过程涉及大量的仿真和实际测试，以收集推力输出和燃料消耗的数据。此外，quasi propulsive coefficient还可以在改善现有技术方面发挥作用。通过分析当前推进系统的性能，工程师可以找出低效之处并进行必要的调整。这可能涉及改变发动机的设计、更换使用的燃料类型，甚至实施先进材料，以减轻重量而不牺牲强度。总之，quasi propulsive coefficient在推进工程领域中作为一个重要工具。它量化推进系统效率的能力使工程师能够在设计和优化过程中做出明智的决策。随着技术的不断进步，理解和利用quasi propulsive coefficient将对开发更高效和有效的推进系统至关重要，这些系统满足现代交通和探索的需求。随着这一领域的持续研究和创新，我们可以期待看到各种推进方法驱动的车辆性能显著改善，最终引领更可持续和高效的交通未来。