centrifugal drainage pattern

简明释义

1. 离心水系; 2. 放射状排水形式; 3. 离心状水系; 4. 放射状水系;

英英释义

例句

1.The geological survey revealed a centrifugal drainage pattern that affected the area's groundwater flow.

地质调查显示出一种离心排水模式，影响了该地区的地下水流动。

2.Farmers often adapt their irrigation systems based on the natural centrifugal drainage pattern of the land.

农民们常常根据土地的自然离心排水模式调整他们的灌溉系统。

3.In civil engineering, understanding a centrifugal drainage pattern is crucial for effective stormwater management.

在土木工程中，理解离心排水模式对有效的雨水管理至关重要。

4.The design of the landscape was influenced by a centrifugal drainage pattern, allowing water to flow away from the center of the garden.

这个景观的设计受到了离心排水模式的影响，使水能够从花园的中心流出。

5.The architect utilized a centrifugal drainage pattern in the roof design to prevent water accumulation.

建筑师在屋顶设计中采用了离心排水模式以防止水的积聚。

作文

In the study of geology and hydrology, understanding various drainage patterns is essential for interpreting landscape evolution and water flow dynamics. One notable type of drainage pattern is the centrifugal drainage pattern, which occurs when water flows outward from a central point, typically found in areas with high elevation or dome-like structures. This pattern can be observed in regions such as volcanic mountains or glacial formations, where the topography encourages water to radiate away from a peak or summit. The centrifugal drainage pattern is characterized by its distinctive shape, resembling the spokes of a wheel. As precipitation falls on the central high point, gravity pulls the water downwards, creating multiple streams that diverge in various directions. This phenomenon not only shapes the physical landscape but also influences the ecological systems within the area. For instance, the distribution of vegetation can be affected by the availability of water, leading to diverse habitats surrounding the central peak.Moreover, the centrifugal drainage pattern plays a significant role in soil erosion and sediment transport. As water flows outward, it can carry sediments away from the center, gradually altering the landscape over time. This process can lead to the formation of alluvial fans at the base of mountains, where sediments accumulate and create fertile land that is often ideal for agriculture.In addition to its geological implications, the centrifugal drainage pattern can have practical applications in urban planning and water resource management. Understanding how water flows in these patterns can help engineers design effective drainage systems that minimize flooding risks and optimize water distribution. For example, in areas prone to heavy rainfall, knowing the centrifugal drainage pattern can aid in the placement of retention basins and stormwater management facilities to control runoff and protect infrastructure.Furthermore, the study of centrifugal drainage patterns extends beyond natural landscapes; it can also be applied in understanding human-made environments. Urban areas often exhibit similar drainage characteristics due to their design and layout. Recognizing these patterns can assist city planners in developing sustainable practices that align with natural water flow, thereby reducing the environmental impact of urbanization.In conclusion, the centrifugal drainage pattern is a vital concept in both geology and hydrology, providing insights into the interaction between water, landforms, and ecosystems. By studying this drainage pattern, researchers and practitioners can better understand the complexities of water movement and its effects on the environment. Whether in natural settings or urban landscapes, the implications of the centrifugal drainage pattern are profound, highlighting the importance of integrating natural processes into planning and conservation efforts. As we continue to face challenges related to climate change and urbanization, recognizing and respecting these natural drainage patterns will be crucial for sustainable development and environmental stewardship.

在地质学和水文学的研究中，理解各种排水模式对于解释地貌演化和水流动态至关重要。一种显著的排水模式是离心排水模式，它发生在水从中心点向外流动的情况下，通常出现在高海拔或圆顶状结构的地区。这种模式可以在火山山脉或冰川形成的区域观察到，在这些地方，地形促使水从峰顶或山顶辐射开来。离心排水模式的特征是其独特的形状，类似于轮子的辐条。当降水落在中央高点时，重力将水拉向下方，形成多个向不同方向发散的溪流。这一现象不仅塑造了物理景观，还影响了该地区的生态系统。例如，植物的分布可能会受到水源可用性的影响，导致围绕中央峰顶形成多样的栖息地。此外，离心排水模式在土壤侵蚀和沉积物运输中也发挥着重要作用。随着水向外流动，它可以将沉积物从中心带走，逐渐改变地貌。这一过程可能导致在山脚形成冲积扇，沉积物聚集并创造出通常适合农业的肥沃土地。除了其地质意义外，离心排水模式在城市规划和水资源管理中也有实际应用。了解水在这些模式中的流动方式可以帮助工程师设计有效的排水系统，以最小化洪水风险并优化水分配。例如，在容易遭受强降雨的地区，了解离心排水模式可以帮助确定蓄水池和雨水管理设施的布置，以控制径流并保护基础设施。此外，离心排水模式的研究不仅限于自然景观；它还可以应用于理解人造环境。城市地区由于其设计和布局，往往表现出类似的排水特征。认识到这些模式可以帮助城市规划者开发与自然水流相协调的可持续实践，从而减少城市化对环境的影响。总之，离心排水模式是地质学和水文学中的一个重要概念，为我们提供了关于水、地貌和生态系统之间相互作用的深刻见解。通过研究这一排水模式，研究人员和从业者可以更好地理解水流动的复杂性及其对环境的影响。无论是在自然环境还是城市景观中，离心排水模式的影响都是深远的，突显了将自然过程融入规划和保护工作的重要性。随着我们继续面临与气候变化和城市化相关的挑战，识别和尊重这些自然排水模式对于可持续发展和环境管理至关重要。