locking circuit

简明释义

保持电路强制同步电路

英英释义

例句

1.The technician tested the locking circuit 锁定电路 to verify that it was functioning correctly.

技术员测试了<锁定电路>以验证其是否正常工作。

2.The locking circuit 锁定电路 is crucial for ensuring the safety of automated systems.

对于确保自动化系统的安全性，<锁定电路>至关重要。

3.The engineer explained how the locking circuit 锁定电路 ensures that the machine cannot operate until all safety guards are in place.

工程师解释了如何通过<锁定电路>确保机器在所有安全防护装置到位之前无法操作。

4.In our new design, the locking circuit 锁定电路 prevents accidental activation of the device during maintenance.

在我们的新设计中，<锁定电路>防止设备在维护期间意外激活。

5.After a power failure, the locking circuit 锁定电路 will automatically reset to prevent unauthorized access.

在停电后，<锁定电路>将自动重置以防止未经授权的访问。

作文

In the realm of electrical engineering, various components and systems are designed to ensure safety, efficiency, and functionality. One such component is the locking circuit, which plays a crucial role in controlling the operation of electrical devices. A locking circuit is a specific type of circuit designed to prevent unauthorized access or operation of a device. This is particularly important in applications where safety and security are paramount, such as in industrial machinery, elevators, and security systems.The principle behind a locking circuit is relatively straightforward. It typically involves the use of switches, relays, and sometimes microcontrollers to create a system that can only be activated under certain conditions. For instance, in an industrial setting, a machine may have a locking circuit that requires a key or a specific sequence of actions to be performed before it can be turned on. This ensures that only trained personnel can operate the machinery, thereby reducing the risk of accidents and injuries.Moreover, locking circuits can also be integrated with safety interlocks. These are mechanisms that automatically shut down a machine if certain safety conditions are not met. For example, if an operator opens a safety guard while the machine is running, the locking circuit will engage and cut off power to the machine, preventing potential harm. This integration enhances the overall safety of the equipment, making it essential in many industries.In addition to safety, locking circuits provide a level of operational efficiency. By ensuring that only authorized personnel can operate certain equipment, organizations can streamline their processes and reduce downtime caused by unauthorized use or accidents. This is particularly vital in environments where machinery is expensive and time-sensitive operations are critical.Furthermore, the concept of a locking circuit extends beyond just physical devices. In software applications, similar principles apply. For instance, access control systems often employ locking circuits in the form of user authentication protocols. These protocols require users to input a password or use biometric identification to gain access to sensitive information or functionalities. Just like in hardware applications, this prevents unauthorized access and ensures that only those with the right credentials can operate the system.The implementation of a locking circuit can vary widely depending on the specific application and requirements. For example, in a residential setting, a simple locking circuit might involve a keypad entry system for a garage door. In contrast, in a large industrial facility, a more complex system involving multiple levels of security and interlocks might be necessary.In conclusion, the locking circuit is an essential component in both electrical and software systems, providing safety, security, and efficiency. Its design and implementation are crucial in preventing unauthorized access and ensuring that devices operate safely. As technology continues to advance, the role of locking circuits will likely evolve, incorporating new methods and technologies to enhance their effectiveness. Understanding the function and importance of locking circuits is vital for anyone involved in electrical engineering or safety management, as they are fundamental to the safe operation of many devices and systems.

在电气工程领域，各种组件和系统的设计旨在确保安全、效率和功能性。其中一个重要的组件是锁定电路，它在控制电气设备的操作中发挥着关键作用。锁定电路是一种特定类型的电路，旨在防止未经授权的访问或设备操作。这在工业机械、电梯和安全系统等安全性和安全性至关重要的应用中尤为重要。锁定电路背后的原理相对简单。它通常涉及使用开关、继电器，有时还有微控制器，创建一个只能在特定条件下激活的系统。例如，在工业环境中，机器可能有一个锁定电路，要求在启动之前必须插入钥匙或执行特定的动作序列。这确保只有经过培训的人员才能操作机器，从而减少事故和伤害的风险。此外，锁定电路还可以与安全联锁装置集成。这些机制会在未满足某些安全条件时自动关闭机器。例如，如果操作员在机器运行时打开安全护罩，锁定电路将启动并切断机器的电源，从而防止潜在的伤害。这种集成增强了设备的整体安全性，使其在许多行业中至关重要。除了安全性，锁定电路还提供了一定程度的操作效率。通过确保只有授权人员可以操作某些设备，组织可以简化流程，减少因未经授权的使用或事故造成的停机时间。这在机器昂贵且时间敏感的操作至关重要的环境中尤为重要。此外，锁定电路的概念不仅限于物理设备。在软件应用中，类似的原则也适用。例如，访问控制系统通常在用户身份验证协议中使用锁定电路。这些协议要求用户输入密码或使用生物识别来访问敏感信息或功能。就像在硬件应用中一样，这防止了未经授权的访问，并确保只有拥有正确凭据的人才能操作系统。锁定电路的实施可能因具体应用和要求而异。例如，在住宅环境中，一个简单的锁定电路可能涉及车库门的数字键盘输入系统。相比之下，在大型工业设施中，可能需要一个更复杂的系统，涉及多个安全级别和联锁装置。总之，锁定电路是电气和软件系统中不可或缺的组件，提供安全性、安全性和效率。它的设计和实施对于防止未经授权的访问和确保设备安全操作至关重要。随着技术的不断进步，锁定电路的角色可能会不断演变，融合新的方法和技术以增强其有效性。理解锁定电路的功能和重要性对于任何参与电气工程或安全管理的人来说都是至关重要的，因为它们是许多设备和系统安全操作的基础。