flapless

简明释义

英[ˈflæpləs]美[ˈflæpləs]

无襟翼的

收上襟翼的

英英释义

单词用法

同义词

反义词

例句

1.Objective: to explore the clinical results of immediate restoration of implants utilizing a flapless approach.

目的：初步对不翻瓣牙种植即刻修复进行临床探讨。

2.Objective: to explore the clinical results of immediate restoration of implants utilizing a flapless approach.

目的：初步对不翻瓣牙种植即刻修复进行临床探讨。

3.Objective:To explore the clinical results of immediate restoration of implants utilizing a flapless approach.

目的探讨各种骨瓣、人工材料在下颌骨缺损即刻修复重建中的临床应用。

4.The new design for the drone features a flapless 无襟翼的 wing structure that improves aerodynamics.

新款无人机的设计采用了flapless 无襟翼的机翼结构，提升了空气动力学性能。

5.Many modern aircraft are moving towards flapless 无襟翼的 technology to reduce drag during flight.

许多现代飞机正在向flapless 无襟翼的技术发展，以减少飞行中的阻力。

6.The flapless 无襟翼的 design allows for smoother transitions during takeoff and landing.

这种flapless 无襟翼的设计使得起飞和降落时的过渡更加平滑。

7.Engineers are testing flapless 无襟翼的 models to enhance fuel efficiency in commercial jets.

工程师们正在测试flapless 无襟翼的模型，以提高商用喷气机的燃油效率。

8.The flapless 无襟翼的 concept is gaining popularity in the field of aerodynamics.

在空气动力学领域，flapless 无襟翼的概念正变得越来越受欢迎。

作文

In recent years, the concept of a flapless design has gained significant attention in various fields, particularly in engineering and architecture. The term flapless refers to a design that does not incorporate flaps or movable surfaces, which are often used to control airflow or movement. This innovative approach has led to numerous advantages, especially in the realm of aerodynamics and structural integrity. One of the most notable applications of flapless technology is in the design of modern aircraft. Traditional aircraft rely heavily on flaps to enhance lift during takeoff and landing. However, engineers have been exploring flapless designs that optimize airflow over the wings without the need for these movable surfaces. By creating wings with a more streamlined shape, they can achieve better aerodynamic efficiency. This not only reduces drag but also improves fuel efficiency, making flights more environmentally friendly. Moreover, flapless designs can lead to simpler mechanical systems. With fewer moving parts, there is less chance of mechanical failure, which enhances the safety and reliability of the aircraft. For instance, some experimental aircraft have successfully demonstrated that flapless wings can still provide adequate lift and maneuverability, challenging the long-held belief that flaps are essential for flight performance. In addition to aviation, the principles of flapless design have found their way into the field of architecture. Architects are increasingly adopting flapless concepts to create buildings that are not only aesthetically pleasing but also structurally sound. For example, the use of cantilevered structures allows for open spaces without the need for additional supports. These designs can withstand natural forces like wind and earthquakes more effectively, showcasing the benefits of a flapless approach in construction. Furthermore, the idea of flapless design extends beyond physical structures to include digital technology. In user interface design, a flapless approach can streamline the user experience by minimizing unnecessary elements and focusing on essential features. This results in cleaner, more intuitive interfaces that enhance user engagement and satisfaction. Overall, embracing a flapless philosophy can lead to innovative solutions across various disciplines. It encourages designers and engineers to think outside the box, challenging conventional methods and seeking new ways to improve functionality and efficiency. As we continue to explore the potential of flapless technologies, it is clear that this approach will play a crucial role in shaping the future of design and engineering. In conclusion, the term flapless signifies a departure from traditional designs that rely on movable parts. Whether in aviation, architecture, or digital technology, flapless concepts offer numerous benefits, including improved efficiency, safety, and aesthetics. As we look forward to future innovations, the flapless approach will undoubtedly continue to inspire creativity and progress in various fields.

近年来，flapless设计的概念在各个领域，特别是在工程和建筑领域，受到了广泛关注。flapless这个术语指的是一种不包含襟翼或可动表面的设计，这些可动表面通常用于控制气流或运动。这种创新的方法带来了许多优势，尤其是在空气动力学和结构完整性方面。 flapless技术最显著的应用之一是在现代飞机的设计中。传统飞机在起飞和着陆时严重依赖襟翼来增强升力。然而，工程师们一直在探索优化机翼气流而无需这些可动表面的flapless设计。通过创建更流线型的机翼形状，他们可以实现更好的空气动力效率。这不仅减少了阻力，还提高了燃油效率，使飞行更加环保。 此外，flapless设计可以导致更简单的机械系统。由于活动部件较少，机械故障的可能性降低，从而增强了飞机的安全性和可靠性。例如，一些实验性飞机成功证明，flapless机翼仍然可以提供足够的升力和操控性，挑战了长期以来认为襟翼对于飞行性能至关重要的观点。 除了航空，flapless设计的原理也进入了建筑领域。建筑师越来越多地采用flapless概念，创造出不仅美观而且结构坚固的建筑。例如，使用悬臂结构可以在不需要额外支撑的情况下创造开放空间。这些设计能够更有效地抵御自然力量，如风和地震，展示了建筑中flapless方法的好处。 此外，flapless设计的理念不仅限于物理结构，还包括数字技术。在用户界面设计中，flapless方法可以通过最小化不必要的元素并专注于基本功能来简化用户体验。这导致更清晰、更直观的界面，增强了用户参与度和满意度。 总的来说，拥抱flapless哲学可以在各个学科中带来创新解决方案。它鼓励设计师和工程师跳出固有思维，挑战传统方法，寻求改善功能和效率的新途径。随着我们继续探索flapless技术的潜力，显然这种方法将在塑造设计和工程的未来中发挥至关重要的作用。 总之，flapless这个术语标志着一种与依赖可动部件的传统设计的背离。无论是在航空、建筑还是数字技术领域，flapless概念都提供了许多好处，包括提高效率、安全性和美学。展望未来的创新，flapless方法无疑将继续激发各个领域的创造力和进步。