indirectly heated thermistor

简明释义

旁热式热敏电阻

英英释义

例句

1.In our research lab, we utilize an indirectly heated thermistor for measuring the temperature of chemical reactions.

在我们的研究实验室中，我们利用间接加热热敏电阻来测量化学反应的温度。

2.The temperature sensor in our new oven uses an indirectly heated thermistor to ensure accurate readings.

我们新烤箱中的温度传感器使用间接加热热敏电阻以确保读数准确。

3.An indirectly heated thermistor is often preferred in high-precision applications due to its stability.

在高精度应用中，通常更倾向于使用间接加热热敏电阻，因为其稳定性较好。

4.For accurate environmental monitoring, we installed an indirectly heated thermistor in the weather station.

为了准确的环境监测，我们在气象站安装了间接加热热敏电阻。

5.The indirectly heated thermistor provides a faster response time compared to traditional sensors.

与传统传感器相比，间接加热热敏电阻提供了更快的响应时间。

作文

In the realm of modern electronics, temperature sensing plays a crucial role in various applications, ranging from consumer electronics to industrial automation. One of the key components in this field is the thermistor, which is a type of resistor whose resistance varies significantly with temperature. Among the different types of thermistors, the indirectly heated thermistor stands out due to its unique design and functionality. Understanding how an indirectly heated thermistor works can provide insights into its applications and advantages over other temperature sensing devices.An indirectly heated thermistor operates on the principle of thermal conduction rather than direct heating. In this setup, the thermistor is heated by a separate heating element, which allows for improved accuracy and response time in temperature measurements. The indirect heating method minimizes self-heating effects that can cause inaccuracies in temperature readings, making the indirectly heated thermistor particularly valuable in precision applications. These thermistors are often used in environments where rapid temperature changes occur or where the thermal mass of the sensing element needs to be minimized. For instance, in medical applications, accurate temperature monitoring is critical, and using an indirectly heated thermistor can lead to more reliable data without the interference of self-heating.The construction of an indirectly heated thermistor typically involves a thermistor bead that is placed near a heating element. This configuration allows the thermistor to react quickly to changes in temperature while being insulated from direct heat. The result is a sensor that can provide real-time data without the lag associated with direct heating methods. Moreover, this design helps to protect the thermistor from potential damage caused by excessive heat, thus extending its lifespan.Another significant advantage of using an indirectly heated thermistor is its versatility. These devices can be incorporated into various systems, including HVAC systems, automotive applications, and even in home appliances. Their ability to maintain accuracy under varying conditions makes them suitable for both commercial and residential uses. Additionally, the compact size of thermistors allows for easy integration into existing designs without requiring significant modifications.In conclusion, the indirectly heated thermistor represents an innovative approach to temperature sensing technology. By utilizing indirect heating methods, these thermistors offer enhanced accuracy, quicker response times, and greater durability compared to traditional thermistors. As technology continues to advance, the demand for precise temperature measurement will only increase, making the indirectly heated thermistor an essential component in the future of electronic devices. Understanding its workings and benefits can help engineers and designers make informed decisions when selecting temperature sensors for their projects.

在现代电子领域，温度传感在各种应用中扮演着至关重要的角色，从消费电子到工业自动化。其中一个关键组件是热敏电阻，它是一种电阻，其电阻值随着温度的变化而显著变化。在不同类型的热敏电阻中，间接加热热敏电阻因其独特的设计和功能而脱颖而出。理解间接加热热敏电阻的工作原理可以提供对其应用和相对于其他温度传感设备的优势的深入了解。间接加热热敏电阻的工作原理基于热传导，而不是直接加热。在这种设置中，热敏电阻由一个单独的加热元件加热，这允许在温度测量中提高准确性和响应时间。间接加热方法最小化了自加热效应，这可能导致温度读数的不准确，使得间接加热热敏电阻在精密应用中尤为宝贵。这些热敏电阻通常用于温度快速变化或需要最小化传感元件热质量的环境。例如，在医疗应用中，准确的温度监测至关重要，使用间接加热热敏电阻可以提供更可靠的数据，而不受自加热的干扰。间接加热热敏电阻的构造通常涉及一个热敏电阻珠，放置在加热元件附近。这种配置使得热敏电阻能够快速反应温度变化，同时避免直接热量的影响。结果是一个能够实时提供数据的传感器，而没有与直接加热方法相关的延迟。此外，这种设计有助于保护热敏电阻免受过热造成的潜在损害，从而延长其使用寿命。使用间接加热热敏电阻的另一个显著优势是其多功能性。这些设备可以被集成到各种系统中，包括暖通空调系统、汽车应用，甚至家庭电器。它们在不同条件下保持准确性的能力使其适合商业和住宅用途。此外，热敏电阻的紧凑尺寸使其能够轻松集成到现有设计中，而无需重大修改。总之，间接加热热敏电阻代表了一种创新的温度传感技术。通过利用间接加热方法，这些热敏电阻提供了比传统热敏电阻更高的准确性、更快的响应时间和更大的耐用性。随着技术的不断进步，对精确温度测量的需求只会增加，这使得间接加热热敏电阻成为未来电子设备中不可或缺的组件。理解其工作原理和优点可以帮助工程师和设计师在选择温度传感器时做出明智的决策。