directly coupled

简明释义

直接耦合的

英英释义

例句

1.The directly coupled system allows for quicker response times.

该直接耦合系统允许更快的响应时间。

2.In this system, the sensors are directly coupled to the control unit.

在这个系统中，传感器直接耦合到控制单元。

3.The two components are directly coupled, eliminating the need for additional gears.

这两个组件直接耦合，消除了对额外齿轮的需求。

4.The motor is directly coupled to the pump for improved efficiency.

电动机与泵直接耦合以提高效率。

5.For optimal performance, the amplifier should be directly coupled to the speaker.

为了最佳性能，放大器应该与扬声器直接耦合。

作文

In modern engineering and technology, the term directly coupled refers to a mechanism where two components are linked in such a way that they operate in unison without any intermediary. This concept is crucial in various fields, including mechanical engineering, electrical systems, and even in software development. Understanding how systems can be directly coupled allows engineers to design more efficient and effective solutions. For instance, consider a simple electric motor that is directly coupled to a pump. In this scenario, the motor drives the pump without any belts or gears in between. This direct connection minimizes energy loss that might occur through friction or slippage in other types of couplings. As a result, the system becomes more efficient, leading to better performance and reduced operational costs. Moreover, directly coupled systems tend to be more reliable. When there are fewer moving parts involved, there is less potential for mechanical failure. This reliability is particularly important in critical applications such as aerospace, where every component must function flawlessly to ensure safety. Engineers strive to create designs that utilize directly coupled mechanisms wherever possible to enhance the overall reliability of their systems. In the realm of software engineering, the idea of directly coupled can also apply. For example, in object-oriented programming, classes that are directly coupled interact with each other directly, sharing data and methods without needing additional layers of abstraction. While this can lead to simpler code and easier debugging, it can also create challenges in terms of maintainability. If one class changes, all directly coupled classes may need to be modified as well. Therefore, while directly coupled systems have their advantages, they also require careful consideration to ensure that they do not lead to overly complex interdependencies. The benefits of directly coupled systems extend beyond efficiency and reliability. They can also lead to significant cost savings. For example, in the automotive industry, manufacturers often use directly coupled components to reduce the number of parts required in a vehicle. This simplification not only lowers production costs but also makes assembly easier and faster. Furthermore, fewer parts mean less inventory management and lower maintenance costs for consumers. However, it is essential to recognize that directly coupled systems are not always the best solution. In some cases, flexibility and adaptability are paramount. For example, in modular design, components may be intentionally designed to be loosely coupled to allow for easy upgrades or replacements. This flexibility can be crucial in industries where technology evolves rapidly. In conclusion, the concept of directly coupled systems plays a vital role in engineering and technology. By understanding how to implement directly coupled mechanisms effectively, engineers can create systems that are more efficient, reliable, and cost-effective. However, it is equally important to balance the benefits of direct coupling with the need for flexibility in design. As technology continues to advance, the application of directly coupled systems will undoubtedly evolve, offering new opportunities and challenges for engineers in the future.

在现代工程和技术中，术语直接耦合指的是两种组件以一种方式连接，使其能够无中介地协同工作。这个概念在机械工程、电气系统，甚至软件开发等多个领域中至关重要。理解系统如何可以直接耦合使工程师能够设计出更高效、更有效的解决方案。例如，考虑一个简单的电动机，它与泵直接耦合。在这种情况下，电动机直接驱动泵，没有任何皮带或齿轮在中间。这种直接连接最小化了可能通过摩擦或滑动在其他类型的耦合中发生的能量损失。因此，系统变得更加高效，导致更好的性能和降低的运营成本。此外，直接耦合的系统往往更可靠。当涉及的运动部件较少时，机械故障的潜在可能性也就减少了。这种可靠性在航空航天等关键应用中特别重要，在这些领域，每个组件必须完美运行以确保安全。工程师们努力创造尽可能使用直接耦合机制的设计，以增强其系统的整体可靠性。在软件工程领域，直接耦合的概念也适用。例如，在面向对象编程中，直接耦合的类直接相互作用，共享数据和方法，而不需要额外的抽象层。虽然这可以导致更简单的代码和更容易的调试，但它也可能在可维护性方面带来挑战。如果一个类发生变化，所有直接耦合的类可能都需要修改。因此，尽管直接耦合的系统有其优点，但它们也需要仔细考虑，以确保不会导致过于复杂的相互依赖。直接耦合系统的好处超越了效率和可靠性。它们还可以带来显著的成本节约。例如，在汽车行业，制造商经常使用直接耦合组件来减少车辆所需的零件数量。这种简化不仅降低了生产成本，还使组装变得更容易、更快速。此外，零件减少意味着更少的库存管理和消费者更低的维护成本。然而，必须认识到直接耦合的系统并不总是最佳解决方案。在某些情况下，灵活性和适应性至关重要。例如，在模块化设计中，组件可能被故意设计为松散耦合，以便于轻松升级或更换。这种灵活性在技术快速发展的行业中可能至关重要。总之，直接耦合系统的概念在工程和技术中发挥着重要作用。通过有效地理解如何实施直接耦合机制，工程师可以创建出更高效、可靠和具成本效益的系统。然而，同样重要的是平衡直接耦合的好处与设计灵活性的需求。随着技术的不断进步，直接耦合系统的应用无疑会发展，为未来的工程师提供新的机遇和挑战。