parasitic loss

简明释义

寄生损失

英英释义

例句

1.The engineers calculated the parasitic loss in the circuit to improve its efficiency.

工程师计算了电路中的寄生损失以提高其效率。

2.In electrical systems, parasitic loss refers to the energy wasted due to resistance in wires.

在电气系统中，寄生损失指的是由于电线中的电阻而浪费的能量。

3.The parasitic loss in the transformer was identified as a major source of heat generation.

变压器中的寄生损失被确定为主要的热量产生源。

4.High temperatures can increase parasitic loss in power cables.

高温会增加电缆中的寄生损失。

5.Reducing parasitic loss is crucial for maximizing battery life in electronic devices.

减少寄生损失对于最大化电子设备的电池寿命至关重要。

作文

In the world of engineering and energy systems, the term parasitic loss refers to the energy that is wasted in a system due to inefficiencies and non-productive processes. This phenomenon is particularly significant in electrical circuits, mechanical systems, and thermal processes where energy is not fully converted into useful work. Understanding parasitic loss is crucial for engineers and designers who aim to enhance the efficiency of their systems and reduce unnecessary energy consumption.For instance, in an electric motor, parasitic loss can occur due to friction between moving parts, heat dissipation in electrical components, and magnetic losses in the core materials. These losses can significantly decrease the overall performance of the motor, leading to higher operational costs and reduced lifespan. By analyzing and minimizing parasitic loss, engineers can create more efficient motors that consume less energy and operate more reliably.Similarly, in thermal systems such as boilers and heat exchangers, parasitic loss can arise from heat escaping to the environment instead of being utilized for heating purposes. Insulation is one method used to mitigate these losses, ensuring that the maximum amount of generated heat is retained within the system. Engineers must consider these factors during the design phase to ensure optimal performance and energy efficiency.The concept of parasitic loss is not limited to mechanical or electrical systems; it also applies to software and data systems. In computing, parasitic loss can manifest as unnecessary data processing, inefficient algorithms, or excessive use of memory resources. These inefficiencies can slow down system performance and increase energy consumption, which is especially critical in data centers where energy costs are a major concern. By optimizing code and streamlining processes, developers can reduce parasitic loss and improve the overall efficiency of the software.Moreover, the implications of parasitic loss extend beyond individual systems to broader environmental and economic contexts. As global energy demands continue to rise, reducing parasitic loss becomes increasingly important in the fight against climate change. By improving the efficiency of our energy systems, we can lower greenhouse gas emissions and conserve natural resources. This necessitates a collaborative effort among engineers, policymakers, and researchers to innovate and implement solutions that minimize parasitic loss across various sectors.In conclusion, parasitic loss represents a significant challenge in the fields of engineering, energy management, and software development. By understanding its causes and effects, professionals can develop strategies to mitigate these losses, ultimately leading to more efficient systems and a healthier planet. As we move towards a more sustainable future, addressing parasitic loss will be essential for maximizing resource utilization and minimizing waste. Through continued research and innovation, we can pave the way for technologies that not only meet our needs but do so in a manner that is environmentally responsible and economically viable.

在工程和能源系统的世界中，术语寄生损失指的是由于效率低下和非生产性过程而在系统中浪费的能量。这种现象在电路、机械系统和热过程中特别显著，在这些过程中，能量并未完全转化为有用的工作。理解寄生损失对于希望提高系统效率和减少不必要能耗的工程师和设计师至关重要。例如，在电动机中，寄生损失可能由于移动部件之间的摩擦、电气元件中的热散失以及核心材料中的磁损失而发生。这些损失可能显著降低电动机的整体性能，导致更高的运营成本和缩短的使用寿命。通过分析和最小化寄生损失，工程师可以制造出更加高效的电动机，从而消耗更少的能源并更可靠地运行。同样，在热系统如锅炉和热交换器中，寄生损失可能源于热量逃逸到环境中，而不是被用于加热目的。绝缘是减轻这些损失的一种方法，确保生成的最大热量保留在系统内。工程师必须在设计阶段考虑这些因素，以确保最佳性能和能源效率。寄生损失的概念不仅限于机械或电气系统；它也适用于软件和数据系统。在计算中，寄生损失可能表现为不必要的数据处理、低效的算法或过度使用内存资源。这些低效会减慢系统性能并增加能耗，这在数据中心尤其重要，因为能耗成本是一个主要问题。通过优化代码和简化流程，开发人员可以减少寄生损失，提高软件的整体效率。此外，寄生损失的影响超越了单个系统，扩展到更广泛的环境和经济背景。随着全球能源需求的不断上升，减少寄生损失在应对气候变化中变得愈加重要。通过提高能源系统的效率，我们可以降低温室气体排放并节约自然资源。这需要工程师、政策制定者和研究人员之间的合作努力，以创新和实施减少各个领域寄生损失的解决方案。总之，寄生损失在工程、能源管理和软件开发领域代表了一个重大挑战。通过理解其原因和影响，专业人士可以制定策略来缓解这些损失，最终导致更高效的系统和更健康的地球。随着我们朝着更可持续的未来迈进，解决寄生损失将对最大化资源利用和最小化浪费至关重要。通过持续的研究和创新，我们可以为满足我们的需求铺平道路，同时以环保和经济可行的方式做到这一点。