tonne per centimeter immersion in fresh water

简明释义

在淡水中每厘米吃水吨数

英英释义

例句

1.The engineer explained that the tonne per centimeter immersion in fresh water is crucial for designing floating structures.

工程师解释说，每厘米浸入淡水的吨数对于设计浮动结构至关重要。

2.To determine how much weight the raft can support, we need to measure its tonne per centimeter immersion in fresh water.

为了确定筏子可以承受多少重量，我们需要测量它的每厘米浸入淡水的吨数。

3.When testing the new vessel, we recorded its tonne per centimeter immersion in fresh water to ensure stability.

在测试新船时，我们记录了它的每厘米浸入淡水的吨数以确保稳定性。

4.The buoyancy of the boat can be calculated using the formula that includes tonne per centimeter immersion in fresh water.

船只的浮力可以通过包含每厘米浸入淡水的吨数的公式进行计算。

5.The formula for calculating displacement includes the tonne per centimeter immersion in fresh water measurement.

计算排水量的公式包括每厘米浸入淡水的吨数的测量。

作文

Understanding the concept of density and buoyancy is essential in various fields, including engineering, physics, and environmental science. One specific measurement that often arises in these disciplines is the idea of tonne per centimeter immersion in fresh water. This phrase refers to the weight of an object measured in tonnes for every centimeter it is submerged in fresh water. To grasp this concept fully, we must delve into the principles of density and buoyancy.Density is defined as mass per unit volume. In the context of water, fresh water has a standard density of approximately 1 tonne per cubic meter. This means that for every cubic meter of fresh water, there is a mass of one tonne. When an object is placed in water, it displaces a volume of water equal to the volume of the object submerged. According to Archimedes' principle, the buoyant force acting on the object is equal to the weight of the water displaced by the object.When we talk about tonne per centimeter immersion in fresh water, we are essentially discussing how much weight corresponds to a certain depth of an object in water. For example, if a large block of metal is partially submerged in fresh water, the amount of water it displaces will determine how much of it is submerged. If the block weighs 10 tonnes and is submerged to a depth of 5 centimeters, we can say that it experiences a buoyant force equal to the weight of the water displaced at that depth.The practical applications of understanding tonne per centimeter immersion in fresh water are vast. In marine engineering, for instance, designing ships and submarines requires precise calculations of buoyancy and stability. Engineers must ensure that the vessels can carry their intended loads without sinking or capsizing. By knowing how much weight corresponds to each centimeter of immersion, they can predict how much cargo a ship can safely transport.In environmental science, this measurement can also play a critical role. When assessing the impact of pollution or sedimentation in bodies of water, scientists may use the concept of tonne per centimeter immersion in fresh water to evaluate how much debris or contaminants are affecting the water's density and overall health. Understanding these dynamics helps in conservation efforts and in maintaining healthy aquatic ecosystems.Moreover, in recreational activities such as diving or swimming, understanding how different objects behave in water based on their weight and shape can enhance safety and enjoyment. For instance, divers must be aware of how their equipment affects their buoyancy, which is directly related to the principles behind tonne per centimeter immersion in fresh water. Knowing how much they weigh versus how much water they displace can help them control their depth and movement underwater.In conclusion, the phrase tonne per centimeter immersion in fresh water encapsulates a fundamental principle of physics that has practical implications across various fields. By grasping the relationship between weight, volume, and buoyancy, we can apply this knowledge to solve real-world problems, whether in engineering, environmental science, or recreational activities. This understanding allows us to innovate and create solutions that respect the natural laws governing our world while enhancing our capabilities within it.

理解密度和浮力的概念在工程学、物理学和环境科学等多个领域至关重要。在这些学科中，一个特定的测量常常出现，即“每厘米浸入淡水的吨数（tonne per centimeter immersion in fresh water）”。这个短语指的是一个物体在淡水中每浸入一厘米所测得的以吨为单位的重量。要充分掌握这一概念，我们必须深入了解密度和浮力的原理。密度被定义为单位体积的质量。在水的上下文中，淡水的标准密度约为每立方米1吨。这意味着每立方米淡水的质量为1吨。当一个物体放入水中时，它会排开一个与其浸入部分的体积相等的水量。根据阿基米德原理，作用在物体上的浮力等于物体排开的水的重量。当我们谈论“每厘米浸入淡水的吨数（tonne per centimeter immersion in fresh water）”时，我们实际上是在讨论物体在水中某一深度对应的重量。例如，如果一个大型金属块部分浸入淡水中，它排开的水量将决定它的浸入程度。如果这个块重10吨，浸入深度为5厘米，我们可以说它经历的浮力等于在该深度排开的水的重量。理解“每厘米浸入淡水的吨数（tonne per centimeter immersion in fresh water）”的实际应用非常广泛。在海洋工程中，例如，设计船舶和潜艇需要精确计算浮力和稳定性。工程师必须确保这些船只能够安全运输其预期的负载，而不会下沉或倾覆。通过了解每厘米浸入对应的重量，他们可以预测船只能够安全运输多少货物。在环境科学中，这一测量也可能发挥关键作用。当评估污染或沉积物对水体的影响时，科学家可能会利用“每厘米浸入淡水的吨数（tonne per centimeter immersion in fresh water）”的概念来评估多少杂物或污染物影响着水的密度和整体健康。理解这些动态有助于保护工作和维护健康的水生生态系统。此外，在潜水或游泳等休闲活动中，理解不同物体在水中如何根据其重量和形状表现，可以增强安全性和乐趣。例如，潜水员必须意识到他们的设备如何影响他们的浮力，而这直接与“每厘米浸入淡水的吨数（tonne per centimeter immersion in fresh water）”的原理相关。知道他们的重量与排开的水量之间的关系，可以帮助他们控制在水下的深度和运动。总之，短语“每厘米浸入淡水的吨数（tonne per centimeter immersion in fresh water）”概括了一个物理学的基本原理，该原理在多个领域具有实际意义。通过掌握重量、体积和浮力之间的关系，我们可以将这一知识应用于解决现实世界中的问题，无论是在工程、环境科学还是休闲活动中。这种理解使我们能够创新并创造尊重自然法则的解决方案，同时增强我们在其中的能力。