noncontact measurement

简明释义

非接触测量技术

英英释义

例句

1.The use of noncontact measurement in industrial applications allows for precise data collection without damaging the materials being tested.

在工业应用中使用非接触测量可以在不损坏被测试材料的情况下实现精确的数据收集。

2.In medical diagnostics, noncontact measurement techniques can monitor patient vitals from a distance.

在医疗诊断中，非接触测量技术可以远程监测患者的生命体征。

3.The automotive industry increasingly relies on noncontact measurement for quality control processes.

汽车行业越来越依赖于非接触测量进行质量控制流程。

4.Using noncontact measurement methods, engineers can inspect components without interfering with their operation.

工程师可以使用非接触测量方法检查组件，而不干扰其操作。

5.Laser scanners employ noncontact measurement to create detailed 3D models of objects.

激光扫描仪采用非接触测量技术来创建物体的详细3D模型。

作文

In the modern world, technology has revolutionized the way we conduct measurements in various fields. One of the most significant advancements is the concept of noncontact measurement, which refers to techniques that allow for the measurement of objects or phenomena without any physical contact. This method has proven particularly useful in industries such as manufacturing, healthcare, and environmental monitoring. By eliminating the need for direct interaction with the subject being measured, noncontact measurement offers numerous advantages, including increased safety, reduced wear and tear on equipment, and the ability to measure delicate or hazardous materials. For instance, in manufacturing, traditional measurement techniques often involve the use of calipers or gauges that require physical contact with the part. This can lead to inaccuracies if the part is sensitive to pressure or if it is made from fragile materials. With noncontact measurement methods, such as laser scanning or infrared thermography, manufacturers can obtain precise measurements without risking damage to the components. These technologies utilize light or thermal radiation to gather data, which is then processed to provide accurate readings. As a result, production efficiency is enhanced, and the quality of the final products is improved.In the healthcare sector, noncontact measurement plays a crucial role in patient monitoring. For example, devices that measure vital signs, such as heart rate and body temperature, can now do so without the need for invasive procedures. Infrared thermometers, which measure body temperature from a distance, have become particularly popular, especially during health crises like the COVID-19 pandemic. This method minimizes the risk of infection and provides a quick and efficient way to monitor patients’ health. Furthermore, advancements in imaging technologies, such as MRI and ultrasound, rely heavily on noncontact measurement techniques to visualize internal structures without any physical intrusion into the body.Environmental monitoring also benefits greatly from noncontact measurement. Technologies such as remote sensing and aerial surveys allow scientists to collect data about land use, vegetation cover, and atmospheric conditions without disturbing the environment. For example, satellites equipped with sensors can capture images of the Earth’s surface, providing valuable information for climate studies and natural resource management. This approach not only preserves the integrity of ecosystems but also enables researchers to gather data over vast areas that would be impossible to measure using traditional methods.Despite its many advantages, noncontact measurement does come with some challenges. The accuracy of these measurements can be affected by environmental factors such as temperature, humidity, and the presence of obstacles. Additionally, the initial setup costs for advanced noncontact measurement systems can be high, which may deter some organizations from adopting these technologies. However, as technology continues to advance and become more affordable, it is likely that noncontact measurement will become increasingly prevalent across various sectors.In conclusion, noncontact measurement represents a significant leap forward in the way we gather data and conduct assessments in numerous fields. Its ability to provide accurate, safe, and efficient measurements without physical contact makes it an invaluable tool in today’s technologically driven society. As we continue to explore new applications and improve existing technologies, the importance of noncontact measurement will undoubtedly grow, paving the way for innovations that enhance our understanding and interaction with the world around us.

在现代世界中，科技彻底改变了我们在各个领域进行测量的方式。其中一个最重要的进步是“非接触测量”的概念，它指的是允许在没有任何物理接触的情况下对物体或现象进行测量的技术。这种方法在制造、医疗和环境监测等行业中尤其有用。通过消除与被测对象的直接互动，“非接触测量”提供了众多优势，包括提高安全性、减少设备磨损以及能够测量精细或危险的材料。例如，在制造业中，传统的测量技术通常涉及使用卡尺或量具，这些工具需要与零件直接接触。如果零件对压力敏感或由脆弱材料制成，这可能会导致不准确的测量。通过“非接触测量”方法，例如激光扫描或红外热成像，制造商可以在不冒损坏组件风险的情况下获得精确的测量。这些技术利用光或热辐射收集数据，然后处理这些数据以提供准确的读数。因此，生产效率得到了提高，最终产品的质量也得到了改善。在医疗行业，“非接触测量”在患者监测中发挥着至关重要的作用。例如，测量生命体征（如心率和体温）的设备现在可以在没有侵入性程序的情况下进行测量。红外温度计可以从远处测量体温，尤其是在COVID-19大流行等健康危机期间变得特别流行。这种方法最大限度地减少了感染的风险，并提供了一种快速有效的方式来监测患者的健康。此外，诸如MRI和超声波等成像技术在很大程度上依赖于“非接触测量”技术，以可视化内部结构而无需对身体进行任何物理干预。环境监测也极大地受益于“非接触测量”。遥感和航空调查等技术使科学家能够在不干扰环境的情况下收集有关土地使用、植被覆盖和大气条件的数据。例如，配备传感器的卫星可以捕获地球表面的图像，为气候研究和自然资源管理提供宝贵的信息。这种方法不仅保护了生态系统的完整性，而且使研究人员能够在广阔的区域内收集数据，这些区域使用传统方法是不可能测量的。尽管有许多优点，“非接触测量”确实面临一些挑战。这些测量的准确性可能会受到温度、湿度和障碍物存在等环境因素的影响。此外，先进的“非接触测量”系统的初始设置成本可能较高，这可能会阻止一些组织采用这些技术。然而，随着技术的不断进步和变得更加经济实惠，“非接触测量”在各个行业中的普及可能会越来越高。总之，“非接触测量”代表了我们在许多领域收集数据和进行评估方式的重要飞跃。它能够在没有物理接触的情况下提供准确、安全和高效的测量，使其成为当今科技驱动社会中不可或缺的工具。随着我们继续探索新的应用并改进现有技术，“非接触测量”的重要性无疑将会增长，为增强我们对周围世界的理解和互动铺平道路。