convective
简明释义
adj. 对流的;传递性的
英英释义
单词用法
对流热传递 | |
对流云;对疗 |
同义词
| 对流的 | 对流电流 | ||
| 循环的 | 循环系统 | ||
| 热的 | 热能 |
反义词
| 导热的 | The conductive properties of the material allow heat to transfer efficiently. | 该材料的导热性能使热量能够有效传递。 | |
| 辐射的 | Radiative heat transfer occurs through electromagnetic waves. | 辐射热传递是通过电磁波进行的。 |
例句
1.Areas (shaded) illustrate the regions where convective cloud frequency exceeds 30 %.
阴影区表示该区域对流云出现频数超过30%。
2.A star during most of its life is a main-sequence star, which consists of a core, radiative and convective zones, a photosphere, a chromosphere and a corona.
一颗恒星其生命的绝大部分处于主序星阶段,在这一阶段它包含一个核心、辐射区和对流区、光球层、色球层和日冕。
3.The structure of the forward-tilted trough increases the atmospheric instability and caused the severe convective weather.
高空前倾槽的结构加大了大气的垂直不稳定,是引起强对流天气的重要原因。
4.Along and ahead of the slowly moving cold front, heavy convective precipitation fell.
对流性暴雨沿着移动缓慢的冷锋及其前沿地区发生。
5.The integral N-S equation is regarded as a special diffusion equation and the pressure term, convective term are regarded as source terms.
将此N S方程看作一个特殊的扩散方程,将压力项与对流项看作是源项,得到一个积分方程。
6.A new method for numerical solution of convective heat transfer problems is presented.
本文给出了一种求解对流传热问题的分步杂交方法。
7.Boundary surfaces were simultaneously exposed to both radiative heating and convective cooling.
外界辐射加热与对流冷却同时作用于边界表面。
8.During the summer, convective 对流的 processes can lead to the formation of cumulus clouds.
在夏季,对流的过程可能导致积云的形成。
9.In cooking, convective 对流的 heat helps to evenly distribute the temperature in the oven.
在烹饪中,对流的热量有助于在烤箱中均匀分布温度。
10.The engineer designed a system to enhance convective 对流的 heat transfer in the reactor.
工程师设计了一个系统,以增强反应堆中的对流的热传递。
11.The convective 对流的 currents in the ocean play a vital role in regulating climate.
海洋中的对流的洋流在调节气候方面起着至关重要的作用。
12.The weather forecast predicts a strong convective 对流的 storm this afternoon.
天气预报预测今天下午将会有强烈的对流的暴风雨。
作文
In the realm of atmospheric sciences, understanding the processes that govern weather patterns is crucial. One such process is known as convective (对流的) heat transfer, which plays a significant role in the formation of clouds and precipitation. When the sun heats the Earth's surface, the air near the ground warms up and begins to rise. This rising warm air is less dense than the cooler air surrounding it, creating a buoyant effect. As this air ascends, it cools at higher altitudes, leading to the condensation of water vapor and the formation of clouds. This phenomenon is primarily driven by convective (对流的) currents, which are essential for various weather systems, including thunderstorms and hurricanes.The importance of convective (对流的) processes extends beyond just weather; they also have significant implications for climate. For instance, tropical regions experience intense convective (对流的) activity due to the warm temperatures and abundant moisture. This can lead to heavy rainfall and severe storms, impacting ecosystems and human activities alike. Conversely, in polar regions, convective (对流的) activity is minimal, resulting in different climatic conditions that influence global weather patterns.Furthermore, the study of convective (对流的) processes is not limited to meteorology. Engineers and scientists often apply these principles in various fields, such as HVAC (heating, ventilation, and air conditioning) systems, where understanding convective (对流的) heat transfer is vital for designing efficient systems. By optimizing the movement of air and heat within buildings, engineers can create comfortable environments while minimizing energy consumption.In addition to practical applications, convective (对流的) processes are also a subject of extensive research. Scientists utilize advanced modeling techniques to predict convective (对流的) phenomena and their impact on climate change. As global temperatures rise, the intensity and frequency of convective (对流的) storms may increase, leading to more extreme weather events. Understanding these changes is critical for developing strategies to mitigate their effects on communities and ecosystems.In conclusion, the concept of convective (对流的) heat transfer is fundamental to both meteorology and engineering. Its implications reach far beyond the formation of clouds and storms, influencing climate patterns and technological advancements. By deepening our understanding of convective (对流的) processes, we can better prepare for the challenges posed by changing weather patterns and work towards sustainable solutions in various industries.
在大气科学领域,理解支配天气模式的过程至关重要。其中一个过程被称为convective(对流的)热传递,它在云和降水的形成中发挥着重要作用。当太阳加热地球表面时,靠近地面的空气变暖并开始上升。这种上升的暖空气比周围更冷的空气密度小,产生了浮力效应。当这些空气上升时,它在较高的高度冷却,导致水蒸气的凝结和云的形成。这个现象主要由convective(对流的)气流驱动,这对于各种天气系统,包括雷暴和飓风,都是必不可少的。convective(对流的)过程的重要性不仅限于天气;它们对气候也有显著影响。例如,热带地区由于温暖的温度和丰富的水分而经历强烈的convective(对流的)活动。这可能导致强降雨和严重的风暴,对生态系统和人类活动产生影响。相反,在极地地区,convective(对流的)活动很少,导致不同的气候条件,从而影响全球天气模式。此外,convective(对流的)过程的研究并不限于气象学。工程师和科学家经常在多个领域应用这些原理,例如HVAC(供暖、通风和空调)系统,在这些系统中,理解convective(对流的)热传递对于设计高效系统至关重要。通过优化建筑内空气和热量的运动,工程师可以创造舒适的环境,同时最小化能源消耗。除了实际应用,convective(对流的)过程也是广泛研究的主题。科学家利用先进的建模技术来预测convective(对流的)现象及其对气候变化的影响。随着全球温度的升高,convective(对流的)风暴的强度和频率可能增加,导致更极端的天气事件。理解这些变化对于制定减轻其对社区和生态系统影响的策略至关重要。总之,convective(对流的)热传递概念是气象学和工程学的基础。它的影响远远超出了云和风暴的形成,影响气候模式和技术进步。通过加深对convective(对流的)过程的理解,我们可以更好地为应对天气模式变化带来的挑战做好准备,并在各个行业中朝着可持续解决方案努力。
