propulsive arrangement

简明释义

推进装置

英英释义

例句

1.In marine design, a well-optimized propulsive arrangement can enhance fuel economy and speed.

在海洋设计中，优化良好的推进布置可以提高燃油经济性和速度。

2.The propulsive arrangement in this model of the car allows for better handling and acceleration.

这款汽车的推进布置使得操控和加速表现更佳。

3.The propulsive arrangement used in the latest jet engine reduces noise and increases thrust.

最新喷气发动机中使用的推进布置降低了噪音并增加了推力。

4.Researchers are studying various propulsive arrangements to improve drone performance.

研究人员正在研究各种推进布置以提高无人机的性能。

5.The engineers developed a new propulsive arrangement that significantly increased the efficiency of the spacecraft.

工程师们开发了一种新的推进布置，显著提高了航天器的效率。

作文

In the realm of engineering and design, the term propulsive arrangement refers to the systematic configuration of components that generate thrust or movement. This concept is particularly significant in fields such as aerospace engineering, automotive design, and robotics. The effectiveness of a propulsive arrangement can determine the efficiency and performance of a vehicle or machine, influencing everything from speed to fuel consumption.To illustrate this, consider the design of an aircraft. The propulsive arrangement in an airplane typically includes engines, propellers, and aerodynamic structures that work together to create lift and thrust. The placement and type of engines, whether they are jet engines or turboprops, play a crucial role in how effectively the aircraft can ascend and maneuver in the sky. Engineers must carefully analyze various factors, such as weight distribution and air resistance, to optimize the propulsive arrangement for maximum performance.Similarly, in the automotive industry, the propulsive arrangement involves the engine, transmission, and drivetrain layout. A well-designed propulsive arrangement allows for smooth acceleration, better handling, and improved fuel efficiency. For instance, electric vehicles have revolutionized traditional propulsive arrangements by integrating batteries and electric motors in a way that minimizes weight while maximizing power output. This shift has not only enhanced performance but also contributed to more sustainable transportation solutions.In robotics, the propulsive arrangement can vary significantly depending on the intended application of the robot. For ground-based robots, wheels or tracks may be employed, while aerial drones utilize rotors or fixed wings. Each propulsive arrangement must be tailored to meet the specific requirements of the task at hand, whether it be navigating rough terrain or achieving stable flight. Innovations in materials and technology continue to push the boundaries of what is possible in robotic propulsion, leading to more versatile and efficient designs.The importance of a well-thought-out propulsive arrangement extends beyond mere functionality; it also encompasses safety and reliability. In high-stakes environments, such as space exploration or emergency response, the integrity of the propulsive arrangement is paramount. Engineers conduct rigorous testing and simulations to ensure that every component works harmoniously, mitigating risks associated with failure.Moreover, the environmental impact of different propulsive arrangements is becoming increasingly relevant in today’s world. As society moves towards greener technologies, the focus on developing propulsion systems that reduce emissions and energy consumption is more critical than ever. This shift requires innovative thinking and a re-evaluation of traditional propulsive arrangements, pushing engineers to explore alternative fuels and energy sources.In conclusion, the concept of propulsive arrangement is integral to the fields of engineering and design. Whether in aviation, automotive, or robotics, the arrangement of components that facilitate movement is crucial to performance, safety, and sustainability. As technology continues to advance, the potential for new and improved propulsive arrangements will undoubtedly lead to exciting developments, shaping the future of transportation and machinery. Understanding and mastering this concept is essential for anyone involved in these dynamic industries.

在工程和设计领域，术语propulsive arrangement指的是生成推力或运动的组件系统配置。这个概念在航空航天工程、汽车设计和机器人等领域尤为重要。propulsive arrangement的有效性可以决定一个车辆或机器的效率和性能，影响从速度到燃料消耗的方方面面。以飞机的设计为例。在飞机中，propulsive arrangement通常包括发动机、螺旋桨和空气动力学结构，这些组件共同作用以产生升力和推力。发动机的类型和位置，无论是喷气发动机还是涡轮螺旋桨，对飞机如何有效上升和在空中机动起着至关重要的作用。工程师们必须仔细分析各种因素，如重量分布和空气阻力，以优化propulsive arrangement，以实现最佳性能。同样，在汽车工业中，propulsive arrangement涉及发动机、变速器和驱动系统的布局。一个设计良好的propulsive arrangement可以实现平稳加速、更好的操控和更高的燃油效率。例如，电动车通过将电池和电动机集成在一起，以最小化重量同时最大化功率输出，彻底改变了传统的propulsive arrangements。这种转变不仅提高了性能，还促进了更可持续的交通解决方案。在机器人技术中，propulsive arrangement可能会因机器人的预期应用而有显著不同。对于地面机器人，可以使用轮子或履带，而空中无人机则利用旋翼或固定翼。每种propulsive arrangement都必须根据手头任务的特定要求进行定制，无论是导航崎岖地形还是实现稳定飞行。材料和技术的创新不断推动机器人推进的边界，导致更具多功能性和效率的设计。一个精心设计的propulsive arrangement的重要性不仅体现在功能性上；它还包括安全性和可靠性。在高风险环境中，如太空探索或紧急响应，propulsive arrangement的完整性至关重要。工程师们进行严格的测试和模拟，以确保每个组件和谐工作，从而降低故障相关的风险。此外，不同propulsive arrangements的环境影响在当今世界变得越来越相关。随着社会向更绿色的技术迈进，开发减少排放和能源消耗的推进系统的重点比以往任何时候都更加重要。这一转变需要创新思维和对传统propulsive arrangements的重新评估，推动工程师探索替代燃料和能源来源。总之，propulsive arrangement的概念在工程和设计领域中至关重要。无论是在航空、汽车还是机器人领域，促进运动的组件的排列对于性能、安全性和可持续性至关重要。随着技术的不断进步，新型和改进的propulsive arrangements的潜力无疑将导致令人兴奋的发展，塑造交通和机械的未来。理解和掌握这一概念对于任何参与这些动态行业的人来说都是必不可少的。