self maintained discharge

简明释义

自持放电

英英释义

例句

1.In the case of emergency lighting, a self maintained discharge feature is crucial for ensuring lights remain on during power outages.

在应急照明的情况下，自我维持放电功能对于确保停电期间灯光保持亮起至关重要。

2.The new battery technology allows for a self maintained discharge system, ensuring that the device remains operational without manual intervention.

新电池技术允许采用自我维持放电系统，确保设备在无需人工干预的情况下保持运行。

3.Our latest model includes a self maintained discharge mechanism that extends the lifespan of the equipment significantly.

我们最新的型号包括一种自我维持放电机制，显著延长了设备的使用寿命。

4.With a self maintained discharge system, the solar panels can effectively manage their energy without constant monitoring.

通过自我维持放电系统，太阳能电池板可以有效管理其能量，而无需不断监控。

5.The self maintained discharge feature in this generator allows it to automatically regulate its output without user input.

这台发电机中的自我维持放电功能使其能够自动调节输出而无需用户输入。

作文

In today's rapidly evolving world, the concept of self maintained discharge has gained significant attention, especially in the fields of technology and engineering. This term refers to a system's ability to operate independently while managing its own outputs and inputs without the need for external intervention. Understanding this concept is crucial as it can lead to more efficient systems that are capable of sustaining themselves over time.To illustrate the importance of self maintained discharge, consider renewable energy systems such as solar panels. These systems can generate electricity independently by harnessing solar energy. Once installed, they can operate autonomously, producing power without requiring constant human oversight. This autonomy is a key feature of self maintained discharge, as it allows the system to manage its energy production and consumption effectively.Moreover, the advantages of self maintained discharge extend beyond just energy generation. In various industries, automated systems are designed to monitor their performance and make adjustments as necessary. For example, in manufacturing, machines equipped with sensors can detect malfunctions and self-correct or notify operators when maintenance is needed. This reduces downtime and increases productivity, showcasing how self maintained discharge can enhance operational efficiency.The application of self maintained discharge is also evident in environmental management. Systems designed for waste treatment can often function independently, processing waste materials and discharging treated water or gases back into the environment. These systems utilize advanced technologies that allow them to monitor their processes and ensure compliance with environmental regulations without the need for constant human supervision.However, achieving true self maintained discharge requires careful planning and design. Engineers and developers must consider various factors, including system reliability, redundancy, and the ability to adapt to changing conditions. For instance, a solar panel system must be designed to handle fluctuations in sunlight availability, ensuring that it can still produce energy during cloudy days or at night through battery storage.Furthermore, the concept of self maintained discharge raises important questions about sustainability and resource management. As we strive for a more sustainable future, developing systems that can operate independently and efficiently is essential. This independence not only reduces our reliance on non-renewable resources but also minimizes human impact on the environment.In conclusion, the idea of self maintained discharge represents a significant shift towards more autonomous and efficient systems across various sectors. By enabling systems to manage their own operations, we can improve productivity, reduce waste, and promote sustainability. As technology continues to advance, the potential for self maintained discharge will likely expand, leading to innovative solutions that address some of the world's most pressing challenges. Embracing this concept is vital for creating a future where systems can thrive independently, contributing to a more sustainable and efficient world.

在当今快速发展的世界中，‘自我维护排放’的概念引起了广泛关注，尤其是在科技和工程领域。这个术语指的是一个系统能够独立运行，同时管理其自身的输入和输出，而无需外部干预。理解这个概念至关重要，因为它可以导致更高效的系统，这些系统能够在长时间内自我维持。为了说明‘自我维护排放’的重要性，可以考虑可再生能源系统，例如太阳能电池板。这些系统可以通过利用太阳能独立发电。一旦安装，它们可以自主运行，产生电力而不需要持续的人为监督。这种自主性是‘自我维护排放’的关键特征，因为它允许系统有效地管理其能源生产和消费。此外，‘自我维护排放’的优势不仅限于能源生成。在各个行业中，自动化系统被设计用来监控其性能并根据需要进行调整。例如，在制造业中，配备传感器的机器可以检测故障并自我修正或在需要维护时通知操作员。这减少了停机时间，提高了生产力，展示了‘自我维护排放’如何增强运营效率。‘自我维护排放’的应用在环境管理中也显而易见。设计用于废物处理的系统通常可以独立运行，处理废物材料并将处理后的水或气体排放回环境。这些系统利用先进的技术，允许它们监控其过程，并确保遵守环境法规，而无需持续的人为监督。然而，实现真正的‘自我维护排放’需要仔细的规划和设计。工程师和开发人员必须考虑各种因素，包括系统可靠性、冗余性以及适应变化条件的能力。例如，太阳能电池板系统必须设计成能够处理阳光可用性的波动，确保在阴天或晚上通过电池存储仍然可以产生能量。此外，‘自我维护排放’的概念引发了有关可持续性和资源管理的重要问题。随着我们努力实现更可持续的未来，开发能够独立且高效运行的系统至关重要。这种独立性不仅减少了我们对不可再生资源的依赖，还最小化了人类对环境的影响。总之，‘自我维护排放’的理念代表了各个行业向更自主和高效系统的重要转变。通过使系统能够管理自身的操作，我们可以提高生产力，减少浪费，促进可持续性。随着技术的不断进步，‘自我维护排放’的潜力可能会扩大，导致创新解决方案，解决一些世界上最紧迫的挑战。接受这一概念对于创造一个系统能够独立繁荣、为更可持续和高效的世界做出贡献的未来至关重要。