self-maintained discharge

简明释义

自持放电

英英释义

例句

1.In agriculture, self-maintained discharge systems help manage water resources efficiently.

在农业中，自我维持的排放系统有助于有效管理水资源。

2.The new waste management system allows for a self-maintained discharge that minimizes environmental impact.

新废物管理系统允许实现自我维持的排放，从而最小化对环境的影响。

3.The research focused on creating a self-maintained discharge mechanism for industrial applications.

研究集中于为工业应用创建一种自我维持的排放机制。

4.With the self-maintained discharge feature, the device can operate continuously without manual intervention.

通过自我维持的排放功能，该设备可以在没有人工干预的情况下持续运行。

5.The engineers designed the system to ensure self-maintained discharge during emergencies.

工程师们设计了该系统，以确保在紧急情况下实现自我维持的排放。

作文

In recent years, the concept of self-maintained discharge has gained significant attention in various fields, particularly in medical and engineering contexts. This term refers to a system or process that can sustain its operation without external intervention, relying instead on internal mechanisms to maintain its functionality. Understanding this concept is crucial as it can lead to advancements in technology and improvements in patient care.In the medical field, self-maintained discharge can be seen in devices such as insulin pumps or automated drug delivery systems. These devices are designed to monitor a patient’s condition and deliver medication as needed, without requiring constant manual input from healthcare providers. For instance, an insulin pump can automatically adjust the dosage of insulin based on the patient's blood sugar levels, ensuring that they receive the right amount of medication at all times. This not only enhances the quality of life for patients with chronic conditions but also reduces the burden on healthcare systems by minimizing the need for frequent hospital visits.Similarly, in engineering, the idea of self-maintained discharge is often applied in the design of autonomous systems. For example, self-driving cars utilize a range of sensors and algorithms to navigate and make decisions without human intervention. These vehicles can assess their environment, respond to changes in traffic conditions, and even perform maintenance checks autonomously. The implications of this technology are vast, potentially leading to safer roads and more efficient transportation systems.The benefits of self-maintained discharge extend beyond convenience; they also encompass safety and reliability. In critical situations, such as medical emergencies or industrial operations, systems that can operate independently reduce the risk of human error. For instance, in a hospital setting, a self-maintained discharge system that monitors vital signs can alert medical staff to any irregularities without delay, allowing for quicker responses to potential crises.Moreover, the development of self-maintained discharge technologies encourages innovation. Researchers and engineers are continuously exploring new ways to enhance these systems, making them more efficient and user-friendly. This drive for improvement not only leads to better products but also fosters a culture of creativity and problem-solving within industries.However, it is essential to consider the challenges associated with self-maintained discharge. While these systems offer numerous advantages, they also raise concerns regarding security and reliability. For instance, if an automated drug delivery system were to malfunction, it could have dire consequences for a patient’s health. Similarly, autonomous vehicles must be equipped with robust safety measures to prevent accidents caused by technical failures. Therefore, ongoing research and development are necessary to ensure that these systems are both effective and safe for users.In conclusion, the concept of self-maintained discharge represents a significant advancement in technology and healthcare. By enabling systems to operate independently, we can improve efficiency, enhance safety, and ultimately provide better care for patients. As we continue to explore the potential of these technologies, it is crucial to address the associated challenges to maximize their benefits. The future of self-maintained discharge holds great promise, and its successful implementation could transform various industries for the better.

近年来，“自我维持排放”这一概念在医疗和工程等多个领域引起了广泛关注。这个术语指的是一种系统或过程，它能够在没有外部干预的情况下维持其运作，而是依靠内部机制来保持其功能。理解这一概念至关重要，因为它可以推动技术进步和改善患者护理。在医疗领域，“自我维持排放”可以在胰岛素泵或自动药物输送系统等设备中看到。这些设备旨在监测患者的状况，并根据需要提供药物，而无需医疗提供者的持续手动输入。例如，胰岛素泵可以根据患者的血糖水平自动调整胰岛素剂量，确保他们始终获得适量的药物。这不仅提高了慢性病患者的生活质量，还通过减少频繁的医院就诊来减轻医疗系统的负担。同样，在工程领域，“自我维持排放”这一理念常常应用于自主系统的设计中。例如，自动驾驶汽车利用一系列传感器和算法在没有人为干预的情况下进行导航和决策。这些车辆可以评估其环境，响应交通条件的变化，甚至能够自主进行维护检查。这项技术的影响深远，可能导致更安全的道路和更高效的交通系统。“自我维持排放”的好处超越了便利性；它们还涵盖了安全性和可靠性。在关键情况下，例如医疗紧急情况或工业操作，能够独立运行的系统减少了人为错误的风险。例如，在医院环境中，一个监测生命体征的“自我维持排放”系统可以及时提醒医务人员任何异常，从而更快地应对潜在危机。此外，“自我维持排放”技术的发展也鼓励了创新。研究人员和工程师不断探索增强这些系统的新方法，使其更加高效和用户友好。这种改进的驱动力不仅导致了更好的产品，也在各行业内培养了创造力和解决问题的文化。然而，必须考虑与“自我维持排放”相关的挑战。虽然这些系统提供了众多优势，但它们也引发了关于安全性和可靠性的担忧。例如，如果一个自动药物输送系统发生故障，可能会对患者的健康产生严重后果。同样，自动驾驶汽车必须配备强大的安全措施，以防止由于技术故障而导致的事故。因此，持续的研究和开发对于确保这些系统对用户既有效又安全至关重要。总之，“自我维持排放”的概念代表了技术和医疗保健的重大进步。通过使系统能够独立运行，我们可以提高效率，增强安全性，并最终为患者提供更好的护理。随着我们继续探索这些技术的潜力，解决相关挑战以最大化其益处至关重要。“自我维持排放”的未来充满希望，其成功实施可能会彻底改变各个行业。