discharge gap

简明释义

放电间隙

英英释义

例句

1.The research team found a noticeable discharge gap in rural healthcare facilities compared to urban ones.

研究团队发现，与城市医疗机构相比，农村医疗设施存在明显的出院差距。

2.To improve efficiency, the clinic analyzed the discharge gap in their patient flow process.

为了提高效率，诊所分析了他们患者流动过程中的出院差距。

3.A significant discharge gap can lead to increased readmission rates for patients.

显著的出院差距可能导致患者的再入院率增加。

4.Addressing the discharge gap is crucial for enhancing the overall healthcare experience.

解决出院差距对改善整体医疗体验至关重要。

5.The hospital is working to reduce the discharge gap between different departments to ensure timely patient care.

医院正在努力缩小不同部门之间的出院差距以确保及时的患者护理。

作文

In the field of electrical engineering, the term discharge gap refers to the space or distance between two conductive materials where an electric discharge can occur. This phenomenon is crucial in various applications, including capacitors, spark plugs, and even lightning. Understanding the concept of discharge gap is essential for engineers and technicians who design and maintain electrical systems. The discharge gap plays a significant role in determining how much voltage is required for an electric current to jump from one conductor to another. When the voltage reaches a certain level, it can overcome the resistance of the air (or other insulating material) in the gap, resulting in a discharge. This is why the size of the discharge gap is critical; larger gaps generally require higher voltages to initiate a discharge.One common example of discharge gap in action is found in spark plugs used in internal combustion engines. In these devices, the discharge gap must be carefully calibrated to ensure that the spark occurs at the right moment during the engine cycle. If the gap is too wide, the spark may not ignite the fuel-air mixture effectively, leading to poor engine performance. Conversely, if the gap is too narrow, it may lead to excessive wear on the spark plug and potential engine damage.Another application of discharge gap is in capacitors, which store electrical energy. The dielectric material between the plates of a capacitor creates a discharge gap that prevents current from flowing until the voltage across the plates exceeds a certain threshold. Once this threshold is reached, the stored energy can be released rapidly, which is utilized in various electronic circuits.In nature, we also see the effects of discharge gap during thunderstorms. Lightning is essentially a massive electrical discharge that occurs when the voltage between charged clouds and the ground becomes high enough to overcome the discharge gap of air. This natural phenomenon illustrates the power of electrical energy and the importance of understanding discharge gap in both natural and engineered systems.Furthermore, as technology advances, researchers are exploring ways to manipulate discharge gap to improve the efficiency of electrical devices. For instance, advancements in materials science may allow for the development of new insulating materials that can withstand higher voltages, thereby increasing the size of the discharge gap without risking a discharge. This could lead to more efficient power transmission systems and improved safety in electrical devices.In conclusion, the concept of discharge gap is fundamental in understanding how electrical discharges occur in various contexts, from everyday appliances to complex industrial systems. By grasping the principles underlying discharge gap, engineers and scientists can innovate and enhance the performance of electrical systems, ultimately leading to safer and more efficient technologies. As we continue to explore and expand our knowledge in this area, the implications for future advancements in electrical engineering remain vast and promising.

在电气工程领域，术语discharge gap指的是两个导电材料之间的空间或距离，在该处可以发生电气放电。这一现象在各种应用中至关重要，包括电容器、火花塞甚至闪电。理解discharge gap的概念对于设计和维护电气系统的工程师和技术人员来说是必不可少的。discharge gap在确定电流从一个导体跳跃到另一个导体所需的电压方面发挥着重要作用。当电压达到某个水平时，它可以克服间隙中空气（或其他绝缘材料）的阻力，从而导致放电。这就是discharge gap大小至关重要的原因；较大的间隙通常需要更高的电压才能启动放电。discharge gap在内燃机中使用的火花塞中发挥了一个常见的例子。在这些设备中，discharge gap必须经过仔细校准，以确保火花在发动机循环的正确时刻发生。如果间隙过大，火花可能无法有效点燃燃料-空气混合物，从而导致发动机性能不佳。相反，如果间隙过小，可能会导致火花塞过度磨损并可能损坏发动机。discharge gap的另一个应用是在电容器中，电容器用于存储电能。电容器板之间的介电材料形成了一个discharge gap，防止电流流动，直到板间的电压超过某个阈值。一旦达到这个阈值，存储的能量可以迅速释放，这在各种电子电路中被利用。在自然界中，我们也可以看到discharge gap在雷暴期间的影响。闪电本质上是一种巨大的电气放电，当带电云与地面之间的电压变得足够高以克服空气的discharge gap时，就会发生这种现象。这个自然现象说明了电能的力量以及理解discharge gap在自然和工程系统中的重要性。此外，随着技术的进步，研究人员正在探索操控discharge gap的方法，以提高电气设备的效率。例如，材料科学的进步可能使开发新型绝缘材料成为可能，这些材料能够承受更高的电压，从而在不冒放电风险的情况下增加discharge gap的大小。这可能导致更高效的电力传输系统和改善电气设备的安全性。总之，discharge gap的概念在理解各种背景下电气放电的发生方面是基础性的，从日常电器到复杂的工业系统。通过掌握discharge gap背后的原理，工程师和科学家可以创新并提升电气系统的性能，最终导致更安全、更高效的技术。随着我们继续探索和扩展这一领域的知识，电气工程未来发展的潜在影响仍然广阔而充满希望。