engineered safety features

简明释义

外设安全措施

英英释义

例句

1.The software includes engineered safety features to protect user data from breaches.

该软件包含了工程安全特性以保护用户数据免受泄露。

2.Manufacturers are now focusing on engineered safety features to reduce the risk of accidents.

制造商现在专注于工程安全特性以降低事故风险。

3.The building was designed with engineered safety features to withstand earthquakes.

这座建筑设计采用了工程安全特性以抵御地震。

4.The new car model comes with advanced engineered safety features that enhance passenger protection.

这款新车型配备了先进的工程安全特性，增强了乘客的保护。

5.In the aviation industry, engineered safety features are critical for ensuring passenger safety.

在航空行业，工程安全特性对于确保乘客安全至关重要。

作文

In recent years, the concept of safety has become increasingly important in various industries, particularly in transportation and manufacturing. One of the key advancements in ensuring safety is the implementation of engineered safety features, which are specifically designed elements that enhance the protection of users and mitigate risks. These features are a result of meticulous planning and innovative engineering, aimed at preventing accidents and minimizing injuries when they occur.For example, in the automotive industry, modern vehicles are equipped with numerous engineered safety features such as airbags, anti-lock braking systems (ABS), and electronic stability control (ESC). Airbags deploy during a collision to cushion the impact for passengers, while ABS prevents the wheels from locking up during hard braking, allowing drivers to maintain steering control. ESC helps drivers maintain control of their vehicle in slippery conditions by automatically applying brakes to individual wheels. Each of these features is a testament to how engineering can significantly improve safety outcomes on the road.Similarly, in the realm of construction, engineered safety features play a crucial role in protecting workers and ensuring structural integrity. For instance, safety harnesses and guardrails are designed to prevent falls from heights, while reinforced structures can withstand extreme weather conditions and seismic activity. The careful design and integration of these safety elements into construction projects not only protect workers but also ensure the longevity and reliability of buildings and infrastructure.Moreover, the aerospace industry has also seen remarkable advancements through engineered safety features. Modern aircraft are equipped with multiple redundant systems that ensure functionality even if one system fails. For example, fly-by-wire technology allows for precise control of the aircraft, and if a failure occurs, backup systems take over to maintain safety. This level of engineering sophistication is essential for the safety of passengers and crew, demonstrating the critical role that engineered safety features play in aviation.The importance of engineered safety features extends beyond just physical safety; it also encompasses psychological aspects. Knowing that a product or environment is equipped with state-of-the-art safety features can provide users with peace of mind. This sense of security encourages individuals to engage in activities they might otherwise avoid due to fear of accidents, ultimately enhancing their quality of life.However, it is vital to recognize that while engineered safety features significantly reduce risks, they cannot eliminate them entirely. Continuous evaluation and improvement of these features are necessary to keep up with evolving technologies and emerging threats. Additionally, user education is equally important; understanding how to properly use safety features can further enhance their effectiveness.In conclusion, engineered safety features are an essential aspect of modern design across various industries. They represent the intersection of innovation and responsibility, aiming to protect lives and reduce the likelihood of accidents. As we continue to advance technologically, the focus on creating and implementing effective safety features will remain paramount, ensuring a safer future for all.

近年来，安全的概念在各个行业中变得越来越重要，特别是在交通和制造业中。确保安全的关键进步之一是实施工程安全特性，这些特性是专门设计的元素，旨在增强用户的保护并降低风险。这些特性是经过细致规划和创新工程的结果，旨在防止事故的发生，并在事故发生时尽量减少伤害。例如，在汽车行业，现代车辆配备了许多工程安全特性，如安全气囊、反锁刹车系统（ABS）和电子稳定控制（ESC）。安全气囊在碰撞时展开，以缓冲乘客的冲击，而ABS可以防止车轮在紧急刹车时锁死，从而使驾驶员能够保持转向控制。ESC帮助驾驶员在滑溜的条件下保持对车辆的控制，通过自动对单个车轮施加刹车来实现。这些特性的每一个都证明了工程如何显著改善道路安全结果。同样，在建筑领域，工程安全特性在保护工人和确保结构完整性方面发挥着至关重要的作用。例如，安全带和护栏旨在防止高处坠落，而加固结构则可以抵御极端天气条件和地震活动。这些安全元素在建筑项目中的精心设计和整合不仅保护工人，还确保建筑和基础设施的耐久性和可靠性。此外，航空航天工业通过工程安全特性也取得了显著进展。现代飞机配备了多个冗余系统，即使一个系统发生故障也能确保功能。例如，电传操纵技术允许对飞机进行精确控制，如果发生故障，备份系统会接管以维持安全。这种工程复杂性对于保护乘客和机组人员的安全至关重要，证明了工程安全特性在航空中的重要作用。工程安全特性的重要性不仅限于身体安全；它还包括心理方面。知道某个产品或环境配备了最先进的安全特性，可以给用户带来安心。这种安全感鼓励个人参与他们可能因担心事故而避免的活动，从而最终提高他们的生活质量。然而，必须认识到，尽管工程安全特性大大降低了风险，但它们不能完全消除风险。持续评估和改进这些特性是跟上不断发展的技术和新出现威胁的必要条件。此外，用户教育同样重要；了解如何正确使用安全特性可以进一步提高其有效性。总之，工程安全特性是现代设计在各个行业中的重要方面。它们代表了创新与责任的交汇点，旨在保护生命并减少事故的可能性。随着我们技术的不断进步，创建和实施有效安全特性的重点将继续是重中之重，确保所有人的未来更加安全。