thermoscope
简明释义
英[ˈθɜːməʊskəʊp]美[ˈθɜːrməˌskop]
n. [仪] 验温器
英英释义
单词用法
热计读数 | |
使用热计 | |
热计设计 | |
热计测量 |
同义词
| 温度计 | 温度计用于测量体温。 | ||
| 温度计 | A temperature gauge is essential for monitoring engine heat. | 温度计对于监测发动机温度至关重要。 |
反义词
| 绝缘体 | 这个绝缘体防止热量传递。 | ||
| 冷却装置 | The cooling device is essential for maintaining low temperatures. | 冷却装置对于保持低温是必不可少的。 |
例句
1.The normal-temperature thermoscope is a glass-stem thermometer with a sheath, which can display the temperature value of the measured point on site.
所述常温测温计是一种具有护套的玻璃棒式温度计,它能够 现场显示被测点温度值。
2.The invention relates to an intelligent rail temperature alarm device, which belongs to the technical field of thermoscope.
本发明涉及一种智能轨温报警装置。本发明属于测温器具技术领域。
3.Though infrared thermoscope is used to detect the temperature of billet when it is taken out of the stove, precision is still affected because of the oxide layer on the surface.
尽管钢材出炉时,可用红外线测温仪来进行钢材表面温度检测,但因钢材表面存在氧化层,也影响钢材温度检测精度。
4.Though infrared thermoscope is used to detect the temperature of billet when it is taken out of the stove, precision is still affected because of the oxide layer on the surface.
尽管钢材出炉时,可用红外线测温仪来进行钢材表面温度检测,但因钢材表面存在氧化层,也影响钢材温度检测精度。
5.By observing the thermoscope, we can determine how heat affects different materials.
通过观察温度计,我们可以确定热量如何影响不同的材料。
6.The scientist used a thermoscope to measure the temperature changes in the experiment.
科学家使用温度计来测量实验中的温度变化。
7.The teacher demonstrated how to use a thermoscope to her students.
老师向学生演示了如何使用温度计。
8.In the lab, the thermoscope provided accurate readings during the chemical reaction.
在实验室中,温度计在化学反应过程中提供了准确的读数。
9.We need a reliable thermoscope for our outdoor experiments.
我们需要一个可靠的温度计用于户外实验。
作文
The invention of the thermoscope has significantly impacted our understanding of temperature and heat. A thermoscope is an early device used to measure temperature changes, which laid the groundwork for modern thermometers. It was developed in the early 17th century by Galileo Galilei, who sought to create a tool that could visually represent the changes in temperature. The thermoscope operates on the principle that air expands when heated and contracts when cooled. This means that as the temperature rises, the air inside the thermoscope expands, pushing a liquid up a tube or causing a float to rise. Conversely, as the temperature drops, the air contracts, and the liquid level falls. Understanding the function of the thermoscope is essential because it illustrates the fundamental concepts of thermal expansion and contraction. These principles are not only crucial in physics but also in various applications across different fields such as meteorology, engineering, and even cooking. For instance, chefs often rely on precise temperature measurements to ensure their dishes are cooked perfectly. The thermoscope serves as a historical reminder of how far we have come in measuring temperature accurately.Furthermore, the development of the thermoscope paved the way for more sophisticated devices. After Galileo's initial invention, many scientists contributed to the evolution of temperature measurement tools. The thermoscope eventually led to the creation of the mercury thermometer and later digital thermometers, which provide instant and accurate readings. Each advancement in this field has enhanced our ability to monitor and control temperature in various environments, from laboratories to industrial settings.In addition to its scientific significance, the thermoscope also holds cultural importance. It reflects the curiosity and ingenuity of early scientists who sought to understand the natural world. The quest for knowledge and the desire to quantify our surroundings have driven humanity's progress. The thermoscope symbolizes the beginning of a journey that has resulted in numerous technological advancements that shape our daily lives today.Moreover, the thermoscope can be seen as a precursor to the concept of thermodynamics, a branch of physics that studies the relationships between heat, work, and energy. Understanding these relationships is vital in various scientific disciplines, including chemistry and engineering. The principles derived from the study of the thermoscope continue to influence modern research and applications, demonstrating the lasting impact of this simple yet revolutionary device.In conclusion, the thermoscope is more than just a historical artifact; it represents a significant milestone in the scientific exploration of temperature. By studying the thermoscope, we gain insights into the evolution of temperature measurement and the broader implications of thermal dynamics. As we continue to innovate and explore the realms of science, the legacy of the thermoscope reminds us of the importance of curiosity and the pursuit of knowledge in shaping our understanding of the world around us.
热感仪的发明对我们理解温度和热量产生了重大影响。热感仪是一种早期用于测量温度变化的设备,为现代温度计奠定了基础。它是在17世纪初由伽利略·伽利莱开发的,他试图创造一种能够直观地表示温度变化的工具。热感仪的工作原理是空气在加热时膨胀,冷却时收缩。这意味着,当温度升高时,热感仪内部的空气膨胀,推动液体上升或导致浮子上升。相反,当温度下降时,空气收缩,液体水平下降。理解热感仪的功能至关重要,因为它说明了热膨胀和收缩的基本概念。这些原理不仅在物理学中至关重要,而且在气象学、工程学甚至烹饪等不同领域的各种应用中也很重要。例如,厨师通常依赖精确的温度测量来确保他们的菜肴煮得恰到好处。热感仪作为一个历史的提醒,展示了我们在准确测量温度方面取得的进步。此外,热感仪的发展为更复杂的设备铺平了道路。在伽利略的初步发明之后,许多科学家为温度测量工具的演变做出了贡献。热感仪最终导致了水银温度计和后来的数字温度计的诞生,后者提供即时和准确的读数。该领域的每一次进步都增强了我们在各种环境中监测和控制温度的能力,从实验室到工业环境。除了科学意义外,热感仪还具有文化重要性。它反映了早期科学家的好奇心和创造力,他们试图理解自然世界。对知识的追求和量化我们周围事物的愿望推动了人类的进步。热感仪象征着一段旅程的开始,这段旅程已导致无数技术进步,塑造了我们今天的日常生活。此外,热感仪可以被视为热力学概念的前身,热力学是研究热、功和能量之间关系的物理学分支。理解这些关系在化学和工程等多个科学学科中至关重要。从热感仪的研究中得出的原理继续影响现代研究和应用,证明了这一简单而革命性的设备的持久影响。总之,热感仪不仅仅是一个历史文物;它代表了温度科学探索中的一个重要里程碑。通过研究热感仪,我们获得了对温度测量演变及热动力学广泛影响的深入了解。随着我们继续创新和探索科学的领域,热感仪的遗产提醒我们,在塑造我们对周围世界的理解时,好奇心和知识追求的重要性。
