grid-lead shield

简明释义

栅极引线屏蔽;

英英释义

A grid-lead shield is a type of radiation shielding that utilizes a grid structure made of lead to absorb and block harmful radiation, commonly used in medical and industrial applications.

网格铅屏蔽是一种利用铅制成的网格结构来吸收和阻挡有害辐射的辐射屏蔽,通常用于医疗和工业应用。

例句

1.Using a grid-lead shield helps reduce background noise in the data collection process.

使用格栅铅屏蔽有助于减少数据收集过程中的背景噪声。

2.The design of the grid-lead shield allows for easy access while providing maximum protection.

格栅铅屏蔽的设计允许在提供最大保护的同时便于访问。

3.The technician installed a grid-lead shield to protect the sensitive equipment from electromagnetic interference.

技术人员安装了一个格栅铅屏蔽以保护敏感设备免受电磁干扰。

4.In the laboratory, we use a grid-lead shield to ensure accurate readings during experiments.

在实验室中,我们使用格栅铅屏蔽以确保实验期间的准确读数。

5.The grid-lead shield was crucial for maintaining safety standards in the radiation zone.

在辐射区,格栅铅屏蔽对于维护安全标准至关重要。

作文

In the realm of electrical engineering and safety, the concept of a grid-lead shield plays a crucial role in protecting sensitive equipment and ensuring efficient energy distribution. The term grid-lead shield refers to a protective barrier that is designed to minimize electromagnetic interference (EMI) and safeguard electronic components from potential damage caused by external electric fields. This technology is particularly important in environments where high-voltage power lines and sensitive communication equipment coexist. The importance of a grid-lead shield cannot be overstated, especially as our reliance on electronic devices continues to grow. In modern cities, the power grid is an intricate network that connects various sources of electricity to consumers. However, this grid can also generate unwanted electromagnetic waves that may disrupt the functionality of nearby devices. A grid-lead shield serves to absorb or deflect these waves, creating a safer environment for sensitive electronics. For instance, hospitals rely heavily on medical equipment that requires precise functioning. If a piece of machinery were to experience interference from the power grid, it could lead to inaccurate readings or even malfunctions during critical procedures. Implementing a grid-lead shield around such equipment ensures that they operate without disruption, thereby safeguarding patient health and enhancing the overall reliability of medical services.Moreover, the application of a grid-lead shield extends beyond healthcare. In the telecommunications sector, data centers house servers that manage vast amounts of information. These facilities are often located near power grids, making them susceptible to EMI. By utilizing a grid-lead shield, operators can protect their infrastructure, ensuring consistent service delivery and reducing the risk of data loss.The design and implementation of a grid-lead shield involve careful consideration of materials and construction techniques. Typically, conductive materials such as copper or aluminum are used due to their effectiveness in blocking electromagnetic waves. Engineers must also take into account factors such as frequency range and the specific environment in which the shield will be deployed. This meticulous approach is essential to ensure that the shield functions optimally under varying conditions.As technology continues to advance, the need for effective shielding solutions like the grid-lead shield will only increase. With the advent of smart cities and the Internet of Things (IoT), the interconnectedness of devices raises concerns about security and interference. The grid-lead shield will play a pivotal role in mitigating these risks, providing a reliable solution to protect both infrastructure and data integrity.In conclusion, the grid-lead shield is an indispensable component in the landscape of modern technology. By preventing electromagnetic interference and protecting sensitive equipment, it ensures that our electronic devices function as intended. As we look towards a future increasingly dominated by technology, understanding and implementing solutions like the grid-lead shield will be vital for maintaining efficiency and safety in various sectors, from healthcare to telecommunications. The advancement of such protective measures will not only enhance operational reliability but also foster innovation in how we approach electronic design and infrastructure development.

在电气工程和安全领域,grid-lead shield的概念在保护敏感设备和确保高效能源分配方面发挥着至关重要的作用。术语grid-lead shield指的是一种保护屏障,旨在最小化电磁干扰(EMI),并保护电子元件免受外部电场可能造成的损害。这项技术在高压电力线和敏感通信设备共存的环境中尤为重要。grid-lead shield的重要性不容忽视,尤其是随着我们对电子设备依赖程度的不断增加。在现代城市中,电网是一个复杂的网络,将各种电源连接到消费者。然而,这个电网也可能产生不必要的电磁波,可能会干扰附近设备的功能。grid-lead shield能够吸收或偏转这些波,从而为敏感电子设备创造一个更安全的环境。例如,医院在很大程度上依赖于需要精确运行的医疗设备。如果某台机器受到电网的干扰,可能会导致读数不准确,甚至在关键程序中发生故障。在这样的设备周围实施grid-lead shield确保它们不受干扰地运行,从而保障患者健康,提高医疗服务的整体可靠性。此外,grid-lead shield的应用不仅限于医疗保健。在电信行业,数据中心存放着管理大量信息的服务器。这些设施通常位于电网附近,容易受到电磁干扰。通过利用grid-lead shield,运营商可以保护他们的基础设施,确保服务的一致性并降低数据丢失的风险。grid-lead shield的设计和实施涉及对材料和建造技术的仔细考虑。通常,使用铜或铝等导电材料,因为它们在阻挡电磁波方面非常有效。工程师还必须考虑频率范围以及屏蔽将要部署的特定环境。这种细致入微的方法对于确保屏蔽在不同条件下的最佳功能至关重要。随着技术的不断进步,像grid-lead shield这样的有效屏蔽解决方案的需求只会增加。随着智能城市和物联网(IoT)的出现,设备之间的互联性引发了对安全性和干扰的担忧。grid-lead shield将在减轻这些风险方面发挥关键作用,为保护基础设施和数据完整性提供可靠的解决方案。总之,grid-lead shield是在现代技术领域不可或缺的组成部分。通过防止电磁干扰并保护敏感设备,它确保我们的电子设备按预期运行。当我们展望一个越来越被技术主导的未来时,理解和实施像grid-lead shield这样的解决方案对于维护各个行业的效率和安全至关重要,从医疗保健到电信。此类保护措施的进步不仅将增强操作的可靠性,还将促进我们在电子设计和基础设施开发方面的创新。