holding power to weight ratio

简明释义

抓重比

英英释义

例句

1.The holding power to weight ratio of this crane is crucial for lifting heavy loads safely.

这台起重机的持重能力与重量比对于安全提升重物至关重要。

2.The manufacturer claims that their new adhesive has a better holding power to weight ratio than its competitors.

制造商声称他们的新型粘合剂具有比竞争对手更好的持重能力与重量比。

3.When selecting a fishing reel, consider the holding power to weight ratio to ensure it can handle large catches.

选择钓鱼卷线器时，考虑持重能力与重量比以确保它能够处理大鱼。

4.For parachuting, the holding power to weight ratio of the harness is vital for ensuring a secure landing.

对于跳伞来说，安全带的持重能力与重量比对于确保安全着陆至关重要。

5.In rock climbing, the holding power to weight ratio of your gear determines how safe you will be on the wall.

在攀岩中，你装备的持重能力与重量比决定了你在墙上的安全性。

作文

In the realm of engineering and physics, understanding various ratios can significantly enhance our comprehension of how different systems function. One such crucial ratio is the holding power to weight ratio, which plays a vital role in various applications, particularly in the fields of mechanics and design. This ratio essentially measures the ability of an object or system to hold or support weight relative to its own weight. The holding power to weight ratio is particularly important in industries such as aerospace, automotive, and construction, where safety and efficiency are paramount.To illustrate the significance of the holding power to weight ratio, let us consider the example of a crane. Cranes are designed to lift heavy loads, and their effectiveness is largely determined by this ratio. A crane with a high holding power to weight ratio can lift heavier loads without risking structural failure or tipping over. This means that for every unit of weight the crane itself has, it can safely hold a greater amount of weight. Engineers must carefully calculate this ratio during the design phase to ensure that cranes can operate safely under various conditions.Another example can be found in the world of automotive engineering. When designing vehicles, manufacturers must consider the holding power to weight ratio of different components, especially when it comes to performance and safety. For instance, sports cars are designed with lightweight materials to enhance speed and agility, but they also need to maintain a strong holding power to weight ratio to ensure stability and control. If the ratio is too low, the vehicle may struggle to maintain grip on the road, leading to dangerous situations.The holding power to weight ratio is not only applicable to mechanical systems but also to biological systems. For example, birds have evolved to have a high holding power to weight ratio, allowing them to fly efficiently. Their lightweight bodies enable them to soar through the sky while their wings provide the necessary lift. This adaptation is crucial for their survival, as it allows them to escape predators and find food more effectively.In conclusion, the holding power to weight ratio is a fundamental concept that finds relevance across multiple disciplines. Whether in engineering, automotive design, or biology, understanding this ratio can lead to improved designs and enhanced safety. As technology continues to advance, the importance of optimizing the holding power to weight ratio will only grow, making it an essential consideration for future innovations. By grasping the implications of this ratio, engineers and designers can create more efficient and safer systems, ultimately benefiting society as a whole.

在工程和物理学领域，理解各种比率可以显著增强我们对不同系统如何运作的理解。其中一个至关重要的比率是持重力与自重比，它在机械和设计等多个应用领域中发挥着重要作用。这个比率本质上衡量了一个物体或系统相对于自身重量的承重或支撑重量的能力。持重力与自重比在航空航天、汽车和建筑等行业尤为重要，因为安全性和效率至关重要。为了说明持重力与自重比的重要性，让我们考虑起重机的例子。起重机被设计用于提升重物，其有效性在很大程度上取决于这个比率。具有高持重力与自重比的起重机能够在不冒结构失效或倾覆风险的情况下提升更重的负载。这意味着起重机自身的每单位重量都能够安全地承受更大的重量。工程师必须在设计阶段仔细计算这个比率，以确保起重机在各种条件下都能安全操作。另一个例子可以在汽车工程的世界中找到。在设计车辆时，制造商必须考虑不同组件的持重力与自重比，尤其是在性能和安全性方面。例如，跑车采用轻质材料设计，以增强速度和灵活性，但它们也需要保持强大的持重力与自重比以确保稳定性和控制。如果这个比率过低，车辆可能会难以在道路上保持抓地力，导致危险情况的发生。持重力与自重比不仅适用于机械系统，也适用于生物系统。例如，鸟类进化出高持重力与自重比，使它们能够高效飞行。它们轻巧的身体使它们能够在天空中翱翔，而翅膀则提供必要的升力。这种适应性对它们的生存至关重要，因为它使它们能够更有效地逃避捕食者和寻找食物。总之，持重力与自重比是一个基本概念，在多个学科中都有相关性。无论是在工程、汽车设计还是生物学中，理解这个比率都可以带来更好的设计和更高的安全性。随着技术的不断进步，优化持重力与自重比的重要性只会增加，使其成为未来创新的一个重要考虑因素。通过掌握这个比率的意义，工程师和设计师可以创造出更高效、更安全的系统，最终惠及整个社会。