off design behaviour

简明释义

非设计工况

英英释义

例句

1.In our simulations, we observed off design behaviour that could lead to potential failures in real-world applications.

在我们的模拟中，我们观察到可能导致实际应用中潜在故障的偏离设计行为。

2.The product's off design behaviour was traced back to a flaw in the initial design specifications.

该产品的偏离设计行为被追溯到初始设计规范中的缺陷。

3.The team conducted a thorough analysis to understand the off design behaviour observed in the prototype.

团队进行了彻底分析，以了解原型中观察到的偏离设计行为。

4.The engineer noted that the system exhibited off design behaviour during the stress test, indicating it was not performing as expected.

工程师注意到系统在压力测试中表现出偏离设计行为，这表明它的性能未达到预期。

5.To mitigate off design behaviour, we need to revise our testing protocols and include more edge cases.

为了减轻偏离设计行为，我们需要修订测试协议，并包括更多边缘案例。

作文

In engineering and design, the term off design behaviour refers to the performance of a system or component when it operates outside its intended design parameters. This concept is crucial in various fields, including aerospace, automotive, and mechanical engineering, as it helps engineers understand how their designs will perform under unexpected conditions. For instance, consider an aircraft engine that is designed to operate efficiently at high altitudes. If this engine is subjected to conditions such as low altitude operation or rapid changes in atmospheric pressure, it may exhibit off design behaviour. Understanding these behaviours is essential for ensuring safety and reliability in engineering applications.The significance of studying off design behaviour cannot be overstated. It allows engineers to identify potential failure points and to develop strategies to mitigate risks. For example, during the testing phase of a new aircraft, engineers will often push the aircraft beyond its normal operating limits to observe how it behaves. This testing can reveal critical insights into the off design behaviour of the aircraft’s systems, such as how the engines respond to different altitudes or speeds. By analyzing this data, engineers can make informed decisions about necessary design adjustments or operational guidelines.Moreover, understanding off design behaviour is not only important for safety but also for efficiency. In many cases, an engineered system may encounter conditions where it is not operating at peak efficiency. For example, a car engine designed for highway driving may struggle in stop-and-go traffic, leading to increased fuel consumption and emissions. By studying the off design behaviour of the engine, engineers can optimize its performance across a wider range of operating conditions, ultimately leading to more environmentally friendly and cost-effective vehicles.In addition to practical applications, off design behaviour also has implications for theoretical studies in engineering. Researchers often use computational models to simulate how systems behave under various conditions. These models must account for off design behaviour to accurately predict performance and guide future designs. As technology advances, the ability to model complex systems becomes increasingly sophisticated, allowing for better predictions and improved designs.Ultimately, the study of off design behaviour is an integral part of the engineering design process. It emphasizes the need for flexibility and adaptability in engineering solutions. As we face new challenges in technology and environmental sustainability, understanding how systems perform outside their intended parameters will be vital. Engineers must continue to explore and analyze off design behaviour to ensure that their designs are robust, efficient, and capable of meeting the demands of real-world applications.In conclusion, off design behaviour encompasses the unexpected performance of engineered systems when they operate outside their specified conditions. This understanding is crucial for enhancing safety, improving efficiency, and guiding theoretical research. As we move forward in engineering innovation, the importance of recognizing and addressing off design behaviour will only grow, making it a key focus for engineers and researchers alike.

在工程和设计中，术语off design behaviour指的是系统或组件在超出其预定设计参数时的性能。这个概念在航空航天、汽车和机械工程等多个领域至关重要，因为它帮助工程师理解他们的设计在意外条件下的表现。例如，考虑一个设计用于高空高效运行的飞机发动机。如果该发动机在低空操作或气压快速变化等条件下工作，它可能会表现出off design behaviour。理解这些行为对于确保工程应用的安全性和可靠性至关重要。研究off design behaviour的重要性不容小觑。它使工程师能够识别潜在的故障点，并制定减轻风险的策略。例如，在新飞机的测试阶段，工程师通常会将飞机推向其正常操作极限之外，以观察其行为。这种测试可以揭示飞机系统的关键见解，例如发动机如何响应不同的高度或速度。通过分析这些数据，工程师可以就必要的设计调整或操作指南做出明智的决策。此外，理解off design behaviour不仅对安全重要，还对效率至关重要。在许多情况下，工程系统可能遇到未能在最佳效率下运行的条件。例如，设计用于高速公路驾驶的汽车发动机在频繁停车和加速的交通中可能会挣扎，导致燃油消耗和排放增加。通过研究发动机的off design behaviour，工程师可以优化其在更广泛操作条件下的性能，从而最终导致更环保和成本效益更高的车辆。除了实际应用，off design behaviour在工程理论研究中也有重要意义。研究人员经常使用计算模型来模拟系统在各种条件下的行为。这些模型必须考虑off design behaviour，以准确预测性能并指导未来的设计。随着技术的进步，建模复杂系统的能力变得越来越复杂，从而允许更好的预测和改进设计。最终，研究off design behaviour是工程设计过程不可或缺的一部分。它强调了工程解决方案中灵活性和适应性的必要性。随着我们面临技术和环境可持续性的新挑战，理解系统在其预定参数之外的表现将至关重要。工程师必须继续探索和分析off design behaviour，以确保他们的设计是稳健、高效，并能够满足现实应用的需求。总之，off design behaviour包括工程系统在超出其规定条件时的意外性能。这种理解对增强安全性、提高效率和指导理论研究至关重要。随着我们在工程创新中的不断推进，认识和解决off design behaviour的重要性只会增加，使其成为工程师和研究人员共同关注的关键焦点。