payload capability

简明释义

有效载荷装载能力

英英释义

例句

1.The rocket's payload capability 有效载荷能力 was increased by redesigning its fuel tanks.

通过重新设计燃料箱，火箭的payload capability 有效载荷能力 得到了提升。

2.The satellite's payload capability 有效载荷能力 allows it to carry advanced imaging technology to monitor Earth.

该卫星的payload capability 有效载荷能力 使其能够携带先进成像技术以监测地球。

3.In military operations, understanding the payload capability 有效载荷能力 of aircraft is crucial for mission planning.

在军事行动中，了解飞机的payload capability 有效载荷能力 对于任务规划至关重要。

4.The new drone model has an impressive payload capability 有效载荷能力 of 10 kilograms, allowing it to carry various equipment.

新款无人机的payload capability 有效载荷能力 达到10公斤，可以携带各种设备。

5.Engineers are always looking to enhance the payload capability 有效载荷能力 of cargo ships to maximize efficiency.

工程师们总是希望提升货船的payload capability 有效载荷能力 以最大化效率。

作文

In the realm of aerospace engineering, the term payload capability refers to the maximum weight that a vehicle, such as a rocket or an aircraft, can carry in addition to its own weight. This concept is crucial for various applications, from launching satellites into orbit to transporting goods and passengers efficiently. Understanding payload capability is essential for engineers and designers who aim to optimize the performance of their vehicles while ensuring safety and reliability.The significance of payload capability cannot be overstated, especially in the context of space exploration. For example, when designing a launch vehicle, engineers must calculate how much payload can be sent into space without compromising the rocket's structural integrity or propulsion efficiency. A higher payload capability allows for more significant scientific instruments or larger satellites to be deployed, which can lead to groundbreaking discoveries and advancements in technology.Moreover, the payload capability of an aircraft plays a vital role in commercial aviation. Airlines need to balance the weight of passengers and cargo with fuel requirements to maximize profitability. If an aircraft has a high payload capability, it can accommodate more passengers or freight, thus increasing revenue potential. However, exceeding this capability can lead to safety risks, including compromised flight performance and increased fuel consumption.In military applications, payload capability is equally important. Military aircraft and drones are designed to carry specific types of weapons and equipment. The ability to transport heavier payloads can enhance operational effectiveness during missions. For instance, a drone with a substantial payload capability can carry advanced surveillance equipment or precision-guided munitions, providing strategic advantages on the battlefield.Furthermore, the development of new technologies continuously influences payload capability. Innovations in materials science have led to lighter and stronger materials, allowing vehicles to carry more without increasing their weight. Additionally, advancements in engine technology enable vehicles to achieve greater thrust-to-weight ratios, further enhancing their payload capability. As a result, the aerospace industry is constantly evolving, striving to improve the efficiency and effectiveness of payload transportation.In conclusion, payload capability is a fundamental aspect of aerospace design that impacts various sectors, including commercial aviation, space exploration, and military operations. By understanding and optimizing this capability, engineers can create vehicles that meet the demands of modern society while pushing the boundaries of what is possible. Whether it is launching a satellite, transporting goods, or conducting military operations, the concept of payload capability remains at the forefront of aerospace engineering, driving innovation and progress in the field.Overall, mastering the intricacies of payload capability is essential for anyone involved in the aerospace sector. It not only influences the design and functionality of vehicles but also determines their effectiveness in meeting mission objectives. As we continue to explore new frontiers in aviation and space travel, the importance of payload capability will undoubtedly remain a key consideration for engineers and scientists alike.

在航空航天工程领域，术语有效载荷能力指的是一辆飞行器（如火箭或飞机）能够携带的最大重量，除此之外还包括其自身的重量。这个概念对于各种应用至关重要，从将卫星发射入轨道到高效运输货物和乘客。理解有效载荷能力对工程师和设计师来说是必不可少的，他们旨在优化飞行器的性能，同时确保安全性和可靠性。有效载荷能力的重要性不容小觑，尤其是在太空探索的背景下。例如，在设计发射载具时，工程师必须计算可以发送到太空的有效载荷量，而不损害火箭的结构完整性或推进效率。更高的有效载荷能力允许部署更重要的科学仪器或更大的卫星，这可能导致突破性的发现和技术进步。此外，飞机的有效载荷能力在商业航空中也扮演着至关重要的角色。航空公司需要平衡乘客和货物的重量与燃料需求，以最大化盈利。如果一架飞机具有较高的有效载荷能力，它可以容纳更多的乘客或货物，从而增加收入潜力。然而，超过这一能力可能会导致安全风险，包括飞行性能受损和燃油消耗增加。在军事应用中，有效载荷能力同样重要。军用飞机和无人机被设计为携带特定类型的武器和设备。运输更重有效载荷的能力可以增强任务的操作效果。例如，一架具有较大有效载荷能力的无人机可以携带先进的监视设备或精确制导弹药，从而在战场上提供战略优势。此外，新技术的发展不断影响着有效载荷能力。材料科学的创新导致了更轻且更强的材料，使得飞行器在不增加自身重量的情况下能够携带更多的有效载荷。此外，发动机技术的进步使得飞行器能够实现更高的推重比，进一步增强它们的有效载荷能力。因此，航空航天行业在不断发展，努力提高有效载荷运输的效率和效果。总之，有效载荷能力是航空航天设计的一个基本方面，影响着多个领域，包括商业航空、太空探索和军事行动。通过理解和优化这一能力，工程师能够创造出满足现代社会需求的飞行器，同时推动可能性的边界。无论是发射卫星、运输货物还是进行军事行动，有效载荷能力的概念始终处于航空航天工程的前沿，推动着该领域的创新与进步。总体而言，掌握有效载荷能力的复杂性对于任何参与航空航天行业的人来说都是至关重要的。它不仅影响着飞行器的设计和功能，还决定了它们在实现任务目标中的有效性。随着我们继续探索航空和太空旅行的新前沿，有效载荷能力的重要性无疑将继续成为工程师和科学家们关注的关键考虑因素。