auxiliary power consumption

简明释义

附件功率消耗

英英释义

例句

1.The aircraft's systems are designed to minimize auxiliary power consumption (辅助电力消耗) during flight.

飞机的系统设计旨在最小化飞行期间的辅助电力消耗 (auxiliary power consumption)。

2.In renewable energy systems, managing auxiliary power consumption (辅助电力消耗) is crucial for overall performance.

在可再生能源系统中，管理辅助电力消耗 (auxiliary power consumption)对整体性能至关重要。

3.The new software provides insights into auxiliary power consumption (辅助电力消耗) patterns within the facility.

新软件提供了有关设施内辅助电力消耗 (auxiliary power consumption)模式的见解。

4.Monitoring auxiliary power consumption (辅助电力消耗) helps in identifying potential energy savings in industrial processes.

监测辅助电力消耗 (auxiliary power consumption)有助于识别工业过程中的潜在节能机会。

5.The train's efficiency can be improved by reducing auxiliary power consumption (辅助电力消耗) during idle periods.

通过减少列车在闲置期间的辅助电力消耗 (auxiliary power consumption)，可以提高其效率。

作文

In modern engineering and technology, the term auxiliary power consumption refers to the energy used by auxiliary systems that support the main operations of a machine or system. This concept is particularly important in sectors such as transportation, manufacturing, and energy production. Understanding auxiliary power consumption is crucial for improving efficiency and reducing operational costs.To illustrate, let’s consider a commercial aircraft. An airplane requires significant energy not only for its engines to propel it forward but also for various auxiliary systems such as lighting, climate control, and avionic systems. The auxiliary power consumption in this context includes the energy drawn from the aircraft’s electrical system to power these essential systems while the plane is on the ground or during flight. By optimizing these auxiliary systems, airlines can reduce fuel consumption and improve overall efficiency.Similarly, in the field of renewable energy, understanding auxiliary power consumption is vital. Wind turbines, for example, require power for their control systems and heating elements to prevent ice formation on blades. The energy consumed by these auxiliary components can significantly affect the overall efficiency of the wind farm. By minimizing auxiliary power consumption, operators can enhance the performance of renewable energy sources, making them more viable alternatives to fossil fuels.In the manufacturing industry, auxiliary power consumption can refer to the energy used by machines that assist in the production process, such as conveyor belts, cooling systems, and robotic arms. These auxiliary systems play a crucial role in maintaining production efficiency and product quality. However, excessive energy consumption by these systems can lead to increased operational costs. Therefore, manufacturers are increasingly focusing on energy-efficient designs and technologies to reduce auxiliary power consumption without compromising productivity.Moreover, the concept of auxiliary power consumption is also relevant in the context of electric vehicles (EVs). While driving, EVs consume energy primarily for propulsion, but they also rely on auxiliary systems such as air conditioning, navigation, and infotainment systems. The energy required for these auxiliary functions can impact the vehicle's range. Thus, manufacturers are continuously working on innovations to minimize auxiliary power consumption in EVs to extend their driving range and enhance user experience.In conclusion, auxiliary power consumption is an integral aspect of various industries, impacting efficiency, sustainability, and cost-effectiveness. By understanding and managing this energy consumption, businesses can make informed decisions that lead to improved operational performance. As technology evolves, the focus on minimizing auxiliary power consumption will likely become even more critical, paving the way for advancements in energy efficiency across multiple sectors. Through strategic planning and innovative solutions, companies can achieve a balance between necessary auxiliary functions and energy conservation, ultimately contributing to a more sustainable future.

在现代工程和技术中，术语辅助电力消耗指的是用于支持机器或系统主要操作的辅助系统所消耗的能量。这个概念在交通、制造和能源生产等领域尤为重要。理解辅助电力消耗对于提高效率和降低运营成本至关重要。以商业飞机为例，一架飞机不仅需要大量能量来推动其前进的引擎，还需要为各种辅助系统提供能量，如照明、气候控制和航空电子系统。在这种情况下，辅助电力消耗包括飞机在地面或飞行期间从电气系统中提取的能量，以供这些基本系统使用。通过优化这些辅助系统，航空公司可以减少燃料消耗，提高整体效率。同样，在可再生能源领域，理解辅助电力消耗至关重要。例如，风力涡轮机需要电力来驱动其控制系统和加热元件，以防止叶片上结冰。这些辅助组件所消耗的能量会显著影响风电场的整体效率。通过最小化辅助电力消耗，运营商可以提升可再生能源的性能，使其成为化石燃料更可行的替代品。在制造行业中，辅助电力消耗可以指辅助生产过程的机器所消耗的能量，例如传送带、冷却系统和机器人手臂。这些辅助系统在维持生产效率和产品质量方面发挥着关键作用。然而，这些系统的过度能量消耗可能会导致运营成本增加。因此，制造商越来越关注节能设计和技术，以减少辅助电力消耗而不影响生产力。此外，辅助电力消耗的概念在电动汽车（EV）的背景下也相关。在行驶过程中，电动汽车主要消耗能量用于推进，但它们还依赖于空调、导航和娱乐系统等辅助系统。这些辅助功能所需的能量会影响车辆的续航能力。因此，制造商不断致力于创新，以最小化电动汽车的辅助电力消耗，从而延长其行驶范围并增强用户体验。总之，辅助电力消耗是各个行业的重要组成部分，影响着效率、可持续性和成本效益。通过理解和管理这种能量消耗，企业可以做出明智的决策，从而提高运营绩效。随着技术的发展，最小化辅助电力消耗的关注将变得更加重要，为多个领域的能源效率进步铺平道路。通过战略规划和创新解决方案，公司可以在必要的辅助功能和能源节约之间找到平衡，最终为更可持续的未来做出贡献。