servo brake

简明释义

伺服制动器

英英释义

例句

1.The new model features an advanced servo brake 助力刹车 technology that improves responsiveness.

新车型采用了先进的助力刹车技术，提高了反应速度。

2.Regular maintenance of the servo brake 助力刹车 system is crucial for vehicle safety.

定期维护助力刹车系统对车辆安全至关重要。

3.The car's servo brake 助力刹车 system allows for smoother stops, especially in heavy traffic.

这辆车的助力刹车系统使得在繁忙交通中能够更平稳地停车。

4.If the servo brake 助力刹车 fails, the driver may struggle to stop the vehicle effectively.

如果助力刹车失灵，驾驶员可能会发现很难有效停车。

5.When the driver presses the pedal, the servo brake 助力刹车 enhances the braking force applied to the wheels.

当驾驶员踩下踏板时，助力刹车增强了施加到车轮上的刹车力。

作文

In modern vehicles, safety and efficiency are paramount. One of the key components that contribute to these vital aspects is the braking system. Among various types of brakes, the servo brake (伺服制动器) stands out due to its unique mechanism and advantages. Understanding how a servo brake (伺服制动器) operates can provide insights into its significance in automotive engineering.A servo brake (伺服制动器) is designed to amplify the force applied by the driver on the brake pedal. This amplification occurs through a system that utilizes hydraulic or pneumatic pressure, making it easier for the driver to stop the vehicle with minimal effort. The primary function of a servo brake (伺服制动器) is to enhance braking performance while ensuring that the driver has complete control over the vehicle.The mechanics behind a servo brake (伺服制动器) involve a series of interconnected components. When the driver presses the brake pedal, a master cylinder generates hydraulic pressure. This pressure is then transmitted to the brake calipers, which clamp onto the brake discs to slow down the wheels. However, with a servo brake (伺服制动器), this process is further optimized. The servo mechanism assists in multiplying the force exerted by the driver, allowing for quicker and more responsive braking.One of the most significant benefits of using a servo brake (伺服制动器) is the reduction of physical strain on the driver. In situations where rapid deceleration is necessary, such as during emergency braking, the servo brake (伺服制动器) enables the driver to apply the brakes with less effort. This feature is particularly crucial for larger vehicles that may require more force to achieve effective stopping power.Moreover, the enhanced responsiveness of a servo brake (伺服制动器) contributes to overall vehicle stability. When a driver can engage the brakes quickly and effectively, it minimizes the risk of skidding or losing control. This characteristic is vital for maintaining safety, especially in adverse weather conditions or on slippery surfaces.Another advantage of servo brakes (伺服制动器) is their adaptability. These systems can be integrated with advanced technologies such as anti-lock braking systems (ABS) and electronic stability control (ESC). By working in conjunction with these systems, servo brakes (伺服制动器) enhance the overall performance of the vehicle's braking capabilities. For instance, during heavy braking, ABS prevents wheel lock-up, while the servo brake (伺服制动器) ensures that sufficient force is applied to maintain control.As automotive technology continues to evolve, the role of servo brakes (伺服制动器) will likely expand. Innovations such as regenerative braking and automated driving systems may further integrate with servo brake (伺服制动器) technology, improving energy efficiency and safety. These advancements highlight the importance of understanding how a servo brake (伺服制动器) functions within the broader context of vehicle design.In conclusion, the servo brake (伺服制动器) is a critical component of modern braking systems, providing enhanced safety, efficiency, and control. Its ability to amplify the driver's input not only reduces physical strain but also contributes to better vehicle stability and responsiveness. As we look towards the future of automotive engineering, the servo brake (伺服制动器) will undoubtedly play a significant role in shaping safer and more efficient vehicles.

在现代车辆中，安全性和效率至关重要。制动系统是其中一个关键组件，它有助于这些重要方面。在各种类型的制动器中，伺服制动器（servo brake）因其独特的机制和优势而脱颖而出。理解伺服制动器（servo brake）的工作原理可以提供对其在汽车工程中重要性的深入见解。伺服制动器（servo brake）旨在放大驾驶员在刹车踏板上施加的力量。这种放大通过利用液压或气压的系统实现，使驾驶员能够以最小的努力停车。伺服制动器（servo brake）的主要功能是提高制动性能，同时确保驾驶员对车辆拥有完全的控制权。伺服制动器（servo brake）背后的机械原理涉及一系列相互连接的组件。当驾驶员踩下刹车踏板时，主缸产生液压压力。这种压力随后传递到制动卡钳，卡钳夹紧制动盘以减缓车轮的转动。然而，通过使用伺服制动器（servo brake），这一过程得到了进一步优化。伺服机制帮助放大驾驶员施加的力量，从而实现更快速、更灵敏的制动。使用伺服制动器（servo brake）的一个显著好处是减少驾驶员的身体负担。在需要快速减速的情况下，例如紧急制动，伺服制动器（servo brake）使驾驶员能够以更少的努力施加制动。这一特性对于需要更多力量才能实现有效制动的大型车辆尤为重要。此外，伺服制动器（servo brake）的增强响应能力有助于整体车辆稳定性。当驾驶员能够快速有效地施加制动时，可以最大限度地减少打滑或失去控制的风险。这一特性对于在恶劣天气条件或滑溜路面上保持安全至关重要。伺服制动器（servo brake）的另一个优点是其适应性。这些系统可以与先进技术如防抱死制动系统（ABS）和电子稳定控制（ESC）相结合。通过与这些系统协同工作，伺服制动器（servo brake）增强了车辆制动能力的整体性能。例如，在重刹车过程中，ABS防止车轮锁死，而伺服制动器（servo brake）则确保施加足够的力量以保持控制。随着汽车技术的不断发展，伺服制动器（servo brake）的作用可能会进一步扩大。再生制动和自动驾驶系统等创新可能会与伺服制动器（servo brake）技术进一步集成，提高能效和安全性。这些进展突显了理解伺服制动器（servo brake）在车辆设计更广泛背景中的功能的重要性。总之，伺服制动器（servo brake）是现代制动系统的关键组件，提供增强的安全性、效率和控制力。它放大驾驶员输入的能力不仅减少了身体负担，还促进了更好的车辆稳定性和响应能力。展望未来，伺服制动器（servo brake）无疑将在塑造更安全、更高效的车辆方面发挥重要作用。