self maintained discharge

简明释义

自持放电

英英释义

例句

1.Our new eco-friendly design includes a self maintained discharge system that minimizes environmental impact.

我们的新环保设计包括一个自我维护排放系统，最小化对环境的影响。

2.The hospital's waste management system utilizes self maintained discharge to handle hazardous materials safely.

医院的废物管理系统利用自我维护排放安全处理危险材料。

3.The new water filtration system has a feature for self maintained discharge, ensuring it operates efficiently without manual intervention.

新的水过滤系统具有自我维护排放的功能，确保其在没有人工干预的情况下高效运行。

4.In our latest model, the self maintained discharge mechanism reduces the need for frequent maintenance checks.

在我们最新的型号中，自我维护排放机制减少了频繁维护检查的需要。

5.With the self maintained discharge feature, the industrial machine can operate continuously without downtime.

通过自我维护排放功能，工业机器可以不间断地持续运行。

作文

In the realm of electrical engineering, the term self maintained discharge refers to a phenomenon where a charged system can continue to release energy without the need for an external power source. This concept is particularly significant in the study of capacitors and other energy-storing devices. Understanding self maintained discharge is crucial for engineers who design circuits that require stable and reliable energy output over time.When a capacitor is charged, it stores electrical energy in an electric field. Once the capacitor begins to discharge, it can release this stored energy in a controlled manner. However, in certain conditions, the discharge can become self-sustaining. This means that the energy released can maintain the discharge process without needing additional input from an external source. This characteristic can be advantageous in various applications, such as in power supply systems where continuous energy is needed even when the main source is temporarily unavailable.One practical example of self maintained discharge can be found in some types of flash photography. In these devices, a capacitor is charged to a high voltage, and when the photographer takes a picture, the capacitor discharges rapidly, producing a bright flash of light. If designed correctly, the circuit can allow for a brief period of self maintained discharge, enabling the flash to remain lit for a longer duration without additional charging. This feature enhances the effectiveness of the flash, allowing for better illumination in low-light situations.Another area where self maintained discharge is relevant is in the design of certain types of batteries and energy storage systems. For instance, researchers are exploring how to create batteries that can sustain their discharge rate over extended periods. By incorporating materials that facilitate self maintained discharge, these batteries could potentially offer longer-lasting power supplies for portable electronic devices or renewable energy systems.However, while the concept of self maintained discharge presents exciting possibilities, it also comes with challenges. One of the primary concerns is safety. If a system discharges itself uncontrollably, it could lead to overheating or even explosions. Therefore, engineers must carefully design circuits and systems to manage this phenomenon effectively. This includes implementing safeguards and monitoring mechanisms that can detect when a self maintained discharge is occurring and take appropriate actions to mitigate any risks.In conclusion, understanding self maintained discharge is essential for anyone involved in electrical engineering or related fields. It opens up new avenues for innovation in energy storage and management systems. As technology continues to advance, the ability to harness and control self maintained discharge will likely play a critical role in developing more efficient and sustainable energy solutions. The implications of this phenomenon extend beyond theoretical discussions; they have real-world applications that can significantly impact how we use and conserve energy in our daily lives.

在电气工程领域，短语自维持放电指的是一种现象，即一个带电系统可以在没有外部电源的情况下继续释放能量。这个概念在电容器和其他储能设备的研究中尤为重要。理解自维持放电对设计需要稳定可靠能量输出的电路的工程师至关重要。当电容器充电时，它在电场中存储电能。一旦电容器开始放电，它可以以受控的方式释放这些存储的能量。然而，在某些条件下，放电可能会变得自我维持。这意味着释放的能量可以在不需要外部源的情况下维持放电过程。这种特性在各种应用中都是有利的，例如在电源系统中，当主源暂时不可用时，需要持续的能量。自维持放电的一个实际例子可以在某些类型的闪光摄影中找到。在这些设备中，电容器被充电到高电压，当摄影师拍照时，电容器迅速放电，产生明亮的闪光。如果设计得当，电路可以允许短时间的自维持放电，使闪光灯在没有额外充电的情况下保持点亮更长时间。这个特性增强了闪光灯的有效性，使其在低光环境中提供更好的照明。另一个与自维持放电相关的领域是某些类型的电池和储能系统的设计。例如，研究人员正在探索如何创建能够在较长时间内维持放电率的电池。通过结合促进自维持放电的材料，这些电池可能为便携式电子设备或可再生能源系统提供更持久的电源。然而，尽管自维持放电的概念带来了令人兴奋的可能性，但它也伴随着挑战。主要的关注点之一是安全性。如果一个系统不受控制地放电，可能会导致过热甚至爆炸。因此，工程师必须仔细设计电路和系统，以有效管理这一现象。这包括实施保护措施和监测机制，以检测何时发生自维持放电并采取适当的措施来减轻任何风险。总之，理解自维持放电对任何参与电气工程或相关领域的人来说都是至关重要的。它为能源储存和管理系统的创新开辟了新的途径。随着技术的不断进步，利用和控制自维持放电的能力可能在开发更高效和可持续的能源解决方案中发挥关键作用。这一现象的影响不仅限于理论讨论；它们在我们日常生活中使用和节约能源的方式上具有实际应用，可以显著影响。