discontact-type wave probe

简明释义

非接触式浪高仪

英英释义

例句

1.Using a discontact-type wave probe allows researchers to minimize interference with the water surface.

使用非接触式波探针可以让研究人员尽量减少对水面干扰。

2.During the coastal survey, the team employed a discontact-type wave probe to assess wave patterns.

在海岸调查中，团队使用了非接触式波探针来评估波浪模式。

3.The discontact-type wave probe is essential for studying wave dynamics in fluid mechanics.

非接触式波探针对于研究流体力学中的波动动态至关重要。

4.In our experiment, the discontact-type wave probe helped us gather accurate data without disturbing the water.

在我们的实验中，非接触式波探针帮助我们在不干扰水体的情况下收集准确的数据。

5.The engineer used a discontact-type wave probe to measure the surface waves in the ocean.

工程师使用了一个非接触式波探针来测量海洋表面的波浪。

作文

In the field of oceanography and marine engineering, various tools and technologies are employed to measure and analyze wave characteristics. One such innovative device is the discontact-type wave probe, which plays a crucial role in understanding wave dynamics and their impact on coastal structures. The discontact-type wave probe is designed to measure the height, period, and direction of waves with high accuracy, providing essential data for researchers and engineers alike.The operation of a discontact-type wave probe is based on the principle of detecting changes in water pressure as waves pass over the probe. Unlike traditional wave probes that may come into direct contact with the water surface, the discontact-type wave probe utilizes a non-contact approach. This method minimizes disturbances to the water surface, allowing for more accurate measurements of wave characteristics. By capturing the pressure variations caused by passing waves, this device can provide real-time data that is vital for both academic research and practical applications.One of the significant advantages of using a discontact-type wave probe is its ability to operate in harsh marine environments. Many coastal regions experience extreme weather conditions, including strong winds and turbulent waves. Traditional probes may suffer from wear and tear or may even be damaged in such conditions. However, the robust design of the discontact-type wave probe ensures that it can withstand these challenges, making it a reliable tool for long-term monitoring of wave activity.Furthermore, the data collected by a discontact-type wave probe can be invaluable for various applications. For instance, coastal engineers use this data to design and construct breakwaters, sea walls, and other protective structures. By understanding wave patterns and forces, engineers can create designs that effectively mitigate the impact of waves on shorelines, thereby protecting infrastructure and habitats.In addition to engineering applications, the information gathered from a discontact-type wave probe is also essential for environmental monitoring. Waves play a significant role in shaping coastal ecosystems, and understanding their behavior can help in the conservation of marine life. Researchers studying sediment transport, for example, can utilize data from these probes to assess how waves influence the movement of sand and other materials along the coast.Moreover, the discontact-type wave probe is also used in the context of climate change studies. With rising sea levels and increasing storm intensity, understanding wave dynamics has become more critical than ever. By providing accurate and continuous data on wave behavior, this technology helps scientists predict potential impacts on coastal communities and ecosystems, facilitating better preparedness and response strategies.In conclusion, the discontact-type wave probe represents a significant advancement in wave measurement technology. Its non-contact design, durability, and ability to provide precise data make it an essential tool for researchers and engineers working in marine environments. As we continue to face the challenges posed by climate change and coastal erosion, the role of devices like the discontact-type wave probe will only become more important in safeguarding our coastlines and understanding the complex interactions within marine ecosystems.

在海洋学和海洋工程领域，各种工具和技术被用来测量和分析波浪特征。其中一种创新设备是非接触式波浪探测器，它在理解波浪动力学及其对沿海结构的影响中发挥着重要作用。非接触式波浪探测器旨在高精度地测量波浪的高度、周期和方向，为研究人员和工程师提供必要的数据。非接触式波浪探测器的操作基于检测波浪经过探头时水压变化的原理。与传统的波浪探测器不同，后者可能直接接触水面，非接触式波浪探测器采用非接触方法。这种方法最小化了对水面扰动的影响，从而允许更准确地测量波浪特征。通过捕捉由于经过的波浪引起的压力变化，该设备能够提供实时数据，这对学术研究和实际应用至关重要。使用非接触式波浪探测器的一个显著优势是其在恶劣海洋环境中运行的能力。许多沿海地区经历极端天气条件，包括强风和湍急的波浪。传统探测器可能会因这些条件而磨损或甚至损坏。然而，非接触式波浪探测器的坚固设计确保其能够承受这些挑战，使其成为长期监测波浪活动的可靠工具。此外，非接触式波浪探测器收集的数据对各种应用都至关重要。例如，沿海工程师利用这些数据设计和建造防波堤、海堤和其他保护结构。通过了解波浪模式和力量，工程师可以创建有效减轻波浪对海岸影响的设计，从而保护基础设施和栖息地。除了工程应用，非接触式波浪探测器收集的信息对环境监测也至关重要。波浪在塑造沿海生态系统中发挥着重要作用，理解它们的行为有助于海洋生物的保护。例如，研究沉积物运输的研究人员可以利用这些探头的数据来评估波浪如何影响沿海沙子和其他材料的运动。此外，非接触式波浪探测器还用于气候变化研究。随着海平面上升和风暴强度增加，理解波浪动力学变得比以往任何时候都更加重要。通过提供准确和连续的波浪行为数据，这项技术帮助科学家预测沿海社区和生态系统可能受到的影响，从而促进更好的准备和应对策略。总之，非接触式波浪探测器代表了波浪测量技术的重大进步。其非接触设计、耐用性和提供精确数据的能力使其成为在海洋环境中工作的研究人员和工程师的重要工具。随着我们继续面临气候变化和沿海侵蚀带来的挑战，像非接触式波浪探测器这样的设备在保护我们的海岸线和理解海洋生态系统内复杂相互作用方面的重要性只会愈加突出。