horizontal danger angle

简明释义

水平危险角

英英释义

例句

1.The pilot adjusted the aircraft's position to minimize the effects of the horizontal danger angle.

飞行员调整了飞机的位置，以最小化水平危险角度的影响。

2.During the training session, we learned how to calculate the horizontal danger angle for safe landings.

在培训课程中，我们学习了如何计算安全着陆的水平危险角度。

3.The engineer explained that the horizontal danger angle can affect the stability of the structure.

工程师解释说，水平危险角度会影响结构的稳定性。

4.In maritime navigation, the horizontal danger angle helps determine safe passage through narrow channels.

在海上导航中，水平危险角度有助于确定通过狭窄水道的安全通行。

5.Understanding the horizontal danger angle is crucial for avoiding collisions in air traffic.

理解水平危险角度对避免空中交通碰撞至关重要。

作文

In the field of engineering and safety, understanding various angles and measurements is crucial for ensuring the stability and security of structures. One such term that often comes up in discussions about safety is the horizontal danger angle. This term refers to the specific angle at which a particular load or force can cause a structure to become unstable if it exceeds a certain threshold. It is particularly relevant in areas such as construction, architecture, and even in the design of vehicles. To illustrate the importance of the horizontal danger angle, let us consider a scenario involving a tall building. When engineers design a skyscraper, they must take into account not only the vertical forces acting on the structure but also the horizontal forces, such as wind or seismic activity. The horizontal danger angle helps determine the maximum angle at which these horizontal forces can act without compromising the integrity of the building. If the angle exceeds this limit, there is a risk of structural failure, which could lead to catastrophic consequences.Moreover, the horizontal danger angle is not limited to buildings alone; it can also be applied to other structures like bridges and towers. For example, when assessing a bridge's ability to withstand strong winds, engineers will calculate the horizontal danger angle to ensure that the bridge remains stable and does not sway excessively. This calculation is vital for public safety, as any failure in such structures could result in loss of life and significant economic damage.In addition to its application in civil engineering, the concept of the horizontal danger angle is also pertinent in the automotive industry. When designing vehicles, manufacturers must consider how the vehicle will respond to lateral forces during sharp turns or sudden maneuvers. The horizontal danger angle helps engineers understand the limits of vehicle stability, allowing them to create designs that minimize the risk of rollover accidents. This aspect of vehicle safety is critical, as it directly impacts the lives of drivers and passengers alike.Furthermore, the horizontal danger angle plays a significant role in outdoor activities such as rock climbing and skiing. Climbers, for instance, need to be aware of the angles at which they are positioned to avoid falling. Understanding the horizontal danger angle allows climbers to choose safer routes and make informed decisions about their safety equipment. Similarly, skiers must be mindful of their body positions on slopes to maintain balance and control, especially in steep terrains where the risk of falling increases.In conclusion, the horizontal danger angle is a fundamental concept that spans various fields, including engineering, architecture, automotive design, and outdoor sports. By understanding this angle, professionals can better assess risks and implement safety measures that protect both structures and individuals. As we continue to advance in technology and design, the significance of the horizontal danger angle will only grow, emphasizing the need for rigorous calculations and safety protocols in our built environment and recreational activities.

在工程和安全领域，理解各种角度和测量对于确保结构的稳定性和安全性至关重要。其中一个常常出现在安全讨论中的术语是水平危险角。这个术语指的是特定的角度，在这个角度下，如果某一负载或力量超过某个阈值，就会导致结构变得不稳定。它在建筑、建筑设计甚至车辆设计等领域尤其相关。为了说明水平危险角的重要性，让我们考虑一个涉及高楼大厦的场景。当工程师设计摩天大楼时，他们不仅必须考虑作用于结构的垂直力，还必须考虑水平力，例如风力或地震活动。水平危险角有助于确定这些水平力在不损害建筑完整性的情况下可以作用的最大角度。如果角度超过这个限制，就存在结构失效的风险，这可能导致灾难性的后果。此外，水平危险角不仅限于建筑物；它也适用于其他结构，如桥梁和塔楼。例如，在评估桥梁抵御强风的能力时，工程师将计算水平危险角以确保桥梁保持稳定，不会过度摇晃。这一计算对公众安全至关重要，因为任何此类结构的失败都可能导致生命损失和重大经济损失。除了在土木工程中的应用外，水平危险角的概念在汽车工业中也很重要。在设计车辆时，制造商必须考虑车辆在急转弯或突然机动时如何应对横向力量。水平危险角帮助工程师理解车辆稳定性的极限，使他们能够创建最小化翻车事故风险的设计。这一车辆安全方面至关重要，因为它直接影响到驾驶员和乘客的生命。此外，水平危险角在户外活动如攀岩和滑雪中也扮演着重要角色。例如，攀登者需要意识到他们所处位置的角度，以避免跌落。理解水平危险角使攀登者能够选择更安全的路线，并对他们的安全设备做出明智的决策。同样，滑雪者必须注意他们在坡道上的身体位置，以保持平衡和控制，特别是在陡峭的地形中，跌倒的风险增加。总之，水平危险角是一个基本概念，跨越多个领域，包括工程、建筑、汽车设计和户外运动。通过理解这个角度，专业人士可以更好地评估风险并实施保护结构和个人的安全措施。随着我们在技术和设计方面的不断进步，水平危险角的重要性只会增加，强调了在我们建造的环境和休闲活动中进行严格计算和安全协议的必要性。