ultrasonic sounding

简明释义

超声波测深测

英英释义

例句

1.The marine biologist used ultrasonic sounding to map the ocean floor.

海洋生物学家使用超声波探测来绘制海底地图。

2.The research team implemented ultrasonic sounding to study the behavior of fish in their natural habitat.

研究团队实施了超声波探测来研究鱼类在其自然栖息地中的行为。

3.During the inspection, the technician performed ultrasonic sounding to detect any flaws in the metal structure.

在检查过程中，技术员进行了超声波探测以检测金属结构中的任何缺陷。

4.The construction company relied on ultrasonic sounding to ensure the integrity of the foundation.

建筑公司依靠超声波探测来确保基础的完整性。

5.Using ultrasonic sounding, they were able to identify underwater geological formations.

通过使用超声波探测，他们能够识别水下地质构造。

作文

Ultrasonic technology has revolutionized various fields, particularly in medical imaging and industrial applications. One of the most significant uses of this technology is in the process known as ultrasonic sounding, which involves the emission of sound waves at frequencies higher than the audible range for humans. This technique has proven to be invaluable in several sectors, including healthcare, manufacturing, and environmental studies.In the medical field, ultrasonic sounding is primarily used for diagnostic imaging. Ultrasound machines utilize high-frequency sound waves to create images of organs and tissues inside the body. This non-invasive method allows healthcare professionals to monitor fetal development during pregnancy, assess organ health, and detect abnormalities without the need for invasive procedures. The safety and effectiveness of ultrasonic sounding make it a preferred choice for many medical examinations, as it poses minimal risk to patients compared to other imaging techniques like X-rays or CT scans.In industrial applications, ultrasonic sounding serves as a critical tool for quality control and maintenance. It is employed to detect flaws in materials, such as cracks or voids that may compromise structural integrity. By sending ultrasonic waves through a material, technicians can analyze the reflected sound waves to identify any irregularities. This method is widely used in industries such as aerospace, automotive, and construction, where safety is paramount, and any defect could lead to catastrophic failures.Moreover, ultrasonic sounding has found its place in environmental monitoring. It is used to assess the health of aquatic ecosystems by measuring the density and distribution of fish populations, as well as monitoring pollution levels in water bodies. The ability of ultrasonic waves to penetrate water makes them an effective tool for gathering data without disturbing the natural environment. Researchers can use ultrasonic sounding to track changes in biodiversity and assess the impact of human activities on aquatic life.The science behind ultrasonic sounding lies in the physics of sound waves. When ultrasonic waves travel through a medium, they encounter different materials and boundaries, causing them to reflect, refract, or absorb. By analyzing these interactions, scientists and technicians can gain insights into the properties of the materials being examined. This principle is not only applicable in medical and industrial contexts but also extends to fields such as geology, where ultrasonic sounding can help map underground formations and locate resources like oil and minerals.In conclusion, ultrasonic sounding is a powerful and versatile technology that has transformed how we approach diagnostics, quality control, and environmental conservation. Its ability to provide accurate, non-invasive insights has made it an essential tool in various industries. As technology continues to advance, we can expect further innovations in ultrasonic sounding techniques, expanding their applications and enhancing our understanding of the world around us. The future holds great promise for this remarkable technology, paving the way for safer and more efficient practices across multiple domains.

超声波技术在各个领域都带来了革命性的变化，特别是在医学成像和工业应用中。其中一个重要的应用是被称为超声波探测的过程，它涉及发出高于人类可听范围的声波。这种技术在医疗、制造和环境研究等多个行业中被证明是无价的。在医疗领域，超声波探测主要用于诊断成像。超声波仪器利用高频声波生成体内器官和组织的图像。这种非侵入性的方法使医疗专业人员能够在怀孕期间监测胎儿发育、评估器官健康以及检测异常，而无需进行侵入性程序。超声波探测的安全性和有效性使其成为许多医学检查的首选，因为与其他成像技术（如X射线或CT扫描）相比，它对患者的风险最小。在工业应用中，超声波探测作为质量控制和维护的重要工具。它被用来检测材料中的缺陷，例如可能危及结构完整性的裂缝或空洞。通过将超声波发送通过材料，技术人员可以分析反射的声波，以识别任何不规则性。这种方法在航空航天、汽车和建筑等行业中广泛应用，在这些行业中，安全至关重要，任何缺陷都可能导致灾难性的失败。此外，超声波探测在环境监测中也找到了自己的位置。它被用来评估水生生态系统的健康状况，通过测量鱼类种群的密度和分布，以及监测水体中的污染水平。超声波能够穿透水体，使其成为收集数据的有效工具，而不会干扰自然环境。研究人员可以利用超声波探测跟踪生物多样性的变化，并评估人类活动对水生生物的影响。超声波探测背后的科学原理在于声波的物理学。当超声波通过介质传播时，它们遇到不同的材料和边界，导致反射、折射或吸收。通过分析这些相互作用，科学家和技术人员可以深入了解被检查材料的特性。这一原理不仅适用于医学和工业领域，还扩展到地质学等领域，在那里超声波探测可以帮助绘制地下地层并定位石油和矿物等资源。总之，超声波探测是一项强大而多功能的技术，改变了我们在诊断、质量控制和环境保护方面的方式。它提供准确、非侵入性见解的能力使其成为各个行业的重要工具。随着技术的不断进步，我们可以期待超声波探测技术的进一步创新，扩大其应用范围，增强我们对周围世界的理解。未来对这一卓越技术充满希望，为多个领域的更安全、更高效的实践铺平了道路。