experimental tank

简明释义

试验水池

英英释义

例句

1.In our lab, we have an experimental tank 实验水槽 designed for simulating oceanic conditions.

在我们的实验室里，我们有一个专为模拟海洋条件而设计的实验水槽 experimental tank。

2.The team monitored the growth of algae in the experimental tank 实验水槽 to evaluate its potential as a biofuel source.

团队监测了实验水槽 experimental tank中藻类的生长，以评估其作为生物燃料来源的潜力。

3.Engineers used an experimental tank 实验水槽 to test the buoyancy of new materials for boat construction.

工程师使用实验水槽 experimental tank测试新材料在船只建造中的浮力。

4.The researchers conducted tests in the experimental tank 实验水槽 to study the effects of different water temperatures on fish behavior.

研究人员在实验水槽 experimental tank中进行测试，以研究不同水温对鱼类行为的影响。

5.The experimental tank 实验水槽 was filled with various chemicals to observe their reactions over time.

该实验水槽 experimental tank中填充了各种化学物质，以观察它们随时间的反应。

作文

In the realm of scientific research and engineering, the term experimental tank refers to a controlled environment where various experiments can be conducted, particularly in fields such as fluid dynamics, material science, and environmental studies. These tanks are designed to simulate real-world conditions, allowing researchers to test hypotheses and gather data without the constraints and unpredictability of the outside world. The significance of an experimental tank cannot be overstated, as it provides a vital tool for innovation and discovery.One of the primary uses of an experimental tank is in the study of fluid dynamics. Engineers and scientists utilize these tanks to observe how fluids behave under different conditions, such as varying temperatures, pressures, and flow rates. For instance, when testing new designs for ships or submarines, an experimental tank allows researchers to analyze how water interacts with the hull, helping to improve efficiency and safety.Moreover, experimental tanks are crucial in the field of environmental studies. They can be used to simulate ecosystems, providing insights into how pollutants affect water quality and aquatic life. Researchers can introduce different variables into the tank—such as temperature changes or chemical spills—and observe the results over time. This data is invaluable for developing strategies to mitigate environmental damage and protect natural habitats.In addition to fluid dynamics and environmental science, experimental tanks are also employed in material science. Scientists can test the durability and performance of materials under various conditions by submerging them in different liquids or exposing them to specific pressures. This process is essential for industries that rely on high-performance materials, such as aerospace and automotive manufacturing. By understanding how materials react in an experimental tank, engineers can design safer and more efficient products.Furthermore, the concept of an experimental tank extends beyond physical tanks. In recent years, virtual simulations have become increasingly popular, allowing researchers to create digital models of tanks where they can manipulate variables and observe outcomes without the need for physical prototypes. This approach saves time and resources while still providing valuable insights into complex systems.As we look towards the future, the role of experimental tanks in research and development will likely continue to grow. With advancements in technology, these tanks will become more sophisticated, incorporating sensors and data analytics to enhance the accuracy of experiments. The integration of artificial intelligence could also lead to new discoveries, as machines analyze vast amounts of data generated during experiments, identifying patterns and correlations that human researchers might overlook.In conclusion, the experimental tank serves as a fundamental component in various scientific and engineering disciplines. It provides a controlled setting for researchers to conduct experiments, enabling them to gather critical data and develop innovative solutions to real-world problems. Whether in the study of fluid dynamics, environmental science, or material testing, the experimental tank remains an indispensable tool for advancing knowledge and technology. As research continues to evolve, the importance of these tanks will only increase, paving the way for future breakthroughs that benefit society as a whole.

在科学研究和工程领域，术语实验水槽指的是一个受控环境，在这里可以进行各种实验，特别是在流体动力学、材料科学和环境研究等领域。这些水槽旨在模拟现实世界的条件，使研究人员能够测试假设并收集数据，而不受外部世界的限制和不可预测性。实验水槽的重要性不容小觑，因为它为创新和发现提供了重要工具。实验水槽的主要用途之一是研究流体动力学。工程师和科学家利用这些水槽观察流体在不同条件下的行为，例如变化的温度、压力和流速。例如，在测试新船只或潜艇的设计时，实验水槽使研究人员能够分析水与船体的相互作用，从而帮助提高效率和安全性。此外，实验水槽在环境研究领域至关重要。它们可以用来模拟生态系统，为研究污染物如何影响水质和水生生物提供洞察。研究人员可以向水槽中引入不同的变量，例如温度变化或化学泄漏，并观察结果随时间的变化。这些数据对于制定减轻环境损害和保护自然栖息地的策略至关重要。除了流体动力学和环境科学，实验水槽还用于材料科学。科学家可以通过将材料浸入不同液体或暴露于特定压力下，测试材料在各种条件下的耐久性和性能。这一过程对于依赖高性能材料的行业（如航空航天和汽车制造）至关重要。通过了解材料在实验水槽中的反应，工程师可以设计出更安全、更高效的产品。此外，实验水槽的概念超出了物理水槽。近年来，虚拟模拟变得越来越流行，允许研究人员创建水槽的数字模型，在这里他们可以操纵变量并观察结果，而无需物理原型。这种方法节省了时间和资源，同时仍然提供了对复杂系统的宝贵洞察。展望未来，实验水槽在研究和开发中的作用可能会继续增长。随着技术的进步，这些水槽将变得更加复杂，整合传感器和数据分析，以提高实验的准确性。人工智能的整合也可能导致新的发现，因为机器分析在实验过程中生成的大量数据，识别出人类研究人员可能忽视的模式和关联。总之，实验水槽作为各个科学和工程学科中的基本组成部分。它提供了一个受控环境供研究人员进行实验，使他们能够收集关键数据并开发出创新的解决方案，以应对现实世界的问题。无论是在流体动力学、环境科学还是材料测试的研究中，实验水槽仍然是推动知识和技术进步的重要工具。随着研究的不断发展，这些水槽的重要性只会增加，为未来的突破铺平道路，造福整个社会。