| Sheath diameter | 3 mm |
| Accuracy class/tolerance | A |
Sheath temperature sensor
Sheath temperature sensors, also called sheath resistance temperature detectors or sheath thermocouples depending on the used measuring element, measure the temperature in liquid or gaseous media. The actual temperature sensor (thermocouple or resistance thermometer) is protected by a surrounding sheath, e.g., made of coated stainless steel. To improve heat conduction, a thermally conductive, electrically insulating filling is introduced between the sheath and the sensor. The sheath can be bent for difficult-to-reach measurement locations. ... Read more
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| Accuracy class/tolerance | A |
| Protection class | Protection class 4 |
| Accuracy class/tolerance | A |
| Available customized versions | Jacket length Jacket diameter Measurement range Show all Connection cable length Special sensor construction Immersion sleeve |
| Isolation of the compensation cable | PVC Silicone Kapton |
| Nominal length | 100 mm |
| Isolation of the compensation cable | PVC Silicone Kapton |
| Sheath diameter | 6 mm |
| Sheath material | Inconel 600 |
| Sheath material | 1.4571 |
| Applications | Chemical industry |
| Sheath diameter | 3 mm |
| Nominal length | 500 mm |
| Measurement range | -200 to 1,100 °C |
| Applications | Chemical industry |
| Sheath diameter | 3 mm |
| Nominal length | 100 mm |
| Measurement range | -200 to 1,100 °C |
| Sheath diameter | 3 to 6 mm |
| Nominal length | 100 to 500 mm |
| Measurement range | 400 to 800 °C |
The advantage of a sheathed temperature sensor is its flexibility. Thanks to the flexible sheath, the sensor can be used in confined spaces or in hard-to-reach places where conventional temperature sensors cannot be used. The sheath protects the sensor from external influences such as mechanical stress or chemical substances. The measuring accuracy of a sheath temperature sensor is of high quality. Direct contact between the sensor and the environment allows the temperature to be measured precisely. The sensor provides reliable data that is essential for controlling and monitoring processes in industry.sheath temperature sensors are used in various areas such as the chemical industry, food and beverage production or heating and air conditioning technology. They enable accurate temperature measurement at critical points and contribute to process optimization and safety, making the sheath temperature sensor a useful tool for temperature measurement in industrial applications. With its flexibility and precision, it makes an important contribution to the control and monitoring of processes.
What is a sheath temperature sensor and what is it used for?
A sheath temperature sensor is a sensor that is used to measure the temperature in various applications. It consists of a metal tube that is typically lined with a thermocouple or a resistance thermometer.
The sheath temperature sensor is often used in industrial plants, heating and air conditioning systems, process control systems and other areas where accurate temperature measurement is required. It can be inserted into liquids, gases or solid materials to measure the temperature at the measuring point.
The sheath temperature sensor is used to monitor and control the temperature in various environments and processes. It enables precise measurement and control of the temperature to ensure that the desired conditions are maintained. This can include, for example, monitoring the temperature in a chemical reaction plant, controlling the heating and cooling systems in a building or monitoring the temperature in an oven or a machine.
The sheath temperature sensor is available in different versions that can be adapted to the application and environment. Its precise and reliable measurement makes it an important instrument for temperature monitoring and control in many industrial and everyday situations.
The sheath temperature sensor is often used in industrial plants, heating and air conditioning systems, process control systems and other areas where accurate temperature measurement is required. It can be inserted into liquids, gases or solid materials to measure the temperature at the measuring point.
The sheath temperature sensor is used to monitor and control the temperature in various environments and processes. It enables precise measurement and control of the temperature to ensure that the desired conditions are maintained. This can include, for example, monitoring the temperature in a chemical reaction plant, controlling the heating and cooling systems in a building or monitoring the temperature in an oven or a machine.
The sheath temperature sensor is available in different versions that can be adapted to the application and environment. Its precise and reliable measurement makes it an important instrument for temperature monitoring and control in many industrial and everyday situations.
How does a sheath temperature sensor work?
A sheath temperature sensor is an electronic device that is used to measure the temperature in various applications. It consists of a metal casing that protects the internal components and a built-in temperature sensor.
The temperature sensor inside the sheath can use different technologies, such as a resistance thermometer (RTD), a thermocouple or a semiconductor temperature sensor. These sensors each work in different ways to detect temperature changes.
With an RTD, the electrical resistance of the temperature sensor increases as the temperature rises. This resistance can then be converted into a temperature. A thermocouple uses the Seebeck effect, in which the temperature difference between two different metals generates an electrical voltage. This voltage is then converted into a temperature. A semiconductor temperature sensor uses the attributes of semiconductors to detect temperature changes. The electrical attributes of the semiconductor change with the temperature, allowing the temperature to be measured.
As soon as the temperature sensor has detected the temperature, the signal is forwarded to a transmitter or a control unit that can display or process the measured temperature. The jacket of the temperature sensor protects the sensor from external influences such as moisture, dirt or mechanical stress.
The sheath temperature sensor is used in various industries and applications, such as in heating, ventilation and air conditioning systems, in the food and beverage industry, in medical technology and in the automotive industry.
The temperature sensor inside the sheath can use different technologies, such as a resistance thermometer (RTD), a thermocouple or a semiconductor temperature sensor. These sensors each work in different ways to detect temperature changes.
With an RTD, the electrical resistance of the temperature sensor increases as the temperature rises. This resistance can then be converted into a temperature. A thermocouple uses the Seebeck effect, in which the temperature difference between two different metals generates an electrical voltage. This voltage is then converted into a temperature. A semiconductor temperature sensor uses the attributes of semiconductors to detect temperature changes. The electrical attributes of the semiconductor change with the temperature, allowing the temperature to be measured.
As soon as the temperature sensor has detected the temperature, the signal is forwarded to a transmitter or a control unit that can display or process the measured temperature. The jacket of the temperature sensor protects the sensor from external influences such as moisture, dirt or mechanical stress.
The sheath temperature sensor is used in various industries and applications, such as in heating, ventilation and air conditioning systems, in the food and beverage industry, in medical technology and in the automotive industry.
What different types of sheath temperature sensors are there?
There are different types of sheath temperature sensors that can be used depending on the application and requirements. Here are some examples:
1. PT100/PT1000 temperature sensor: These sensors use platinum as a resistor material and are known for their high accuracy and stability.
2. Thermocouples: Thermocouples consist of two different metals that are welded together at one end. They generate a voltage that is proportional to the temperature difference. Thermocouples are known for their fast response time and wide temperature measuring ranges.
3. NTC temperature sensors: NTC (Negative Temperature Coefficient) sensors use a semiconductor material that reduces its electrical resistance with increasing temperature. They are inexpensive and are often used in household appliances and electronic applications.
4. PTC temperature sensors: PTC (Positive Temperature Coefficient) sensors use a semiconductor material that increases its resistance as the temperature rises. They are often used in heaters and overheating protection devices.
5. Infrared temperature sensors: These sensors measure the surface temperature of an object without direct contact. They detect the heat radiation of the object and convert it into a temperature display.
These are just a few examples of sheath temperature sensors, and there are also other specialized sensors for specific applications and environments.
1. PT100/PT1000 temperature sensor: These sensors use platinum as a resistor material and are known for their high accuracy and stability.
2. Thermocouples: Thermocouples consist of two different metals that are welded together at one end. They generate a voltage that is proportional to the temperature difference. Thermocouples are known for their fast response time and wide temperature measuring ranges.
3. NTC temperature sensors: NTC (Negative Temperature Coefficient) sensors use a semiconductor material that reduces its electrical resistance with increasing temperature. They are inexpensive and are often used in household appliances and electronic applications.
4. PTC temperature sensors: PTC (Positive Temperature Coefficient) sensors use a semiconductor material that increases its resistance as the temperature rises. They are often used in heaters and overheating protection devices.
5. Infrared temperature sensors: These sensors measure the surface temperature of an object without direct contact. They detect the heat radiation of the object and convert it into a temperature display.
These are just a few examples of sheath temperature sensors, and there are also other specialized sensors for specific applications and environments.
What advantages does a sheath temperature sensor offer compared to other temperature measuring devices?
A sheath temperature sensor offers several advantages compared to other temperature measuring devices:
1. Protection against mechanical damage: The sheath around the temperature sensor protects it from external influences such as vibrations, shocks or abrasion. This makes it particularly robust and durable.
2. High measuring accuracy: Due to the direct contact with the medium to be measured, the sheath temperature sensor can measure the temperature very precisely. There is no heat loss or falsification of the measured values.
3. Fast response time: The sheath temperature sensor reacts very quickly to temperature changes and therefore provides quickly updated measured values. This makes it particularly suitable for applications where rapid temperature control is required.
4. Versatile application possibilities: Sheathed temperature sensors can be used in various industries and applications, e.g. in the chemical industry, food processing, medical technology or building automation. They can be used in liquids as well as in gaseous media or solids.
5. Simple installation: Sheath temperature sensors are relatively easy to install and connect to various systems. They are available in different sizes and designs to meet individual requirements.
Overall, sheath temperature sensors offer reliable and precise temperature measurement in demanding environments and are therefore a popular choice in many industrial sectors.
1. Protection against mechanical damage: The sheath around the temperature sensor protects it from external influences such as vibrations, shocks or abrasion. This makes it particularly robust and durable.
2. High measuring accuracy: Due to the direct contact with the medium to be measured, the sheath temperature sensor can measure the temperature very precisely. There is no heat loss or falsification of the measured values.
3. Fast response time: The sheath temperature sensor reacts very quickly to temperature changes and therefore provides quickly updated measured values. This makes it particularly suitable for applications where rapid temperature control is required.
4. Versatile application possibilities: Sheathed temperature sensors can be used in various industries and applications, e.g. in the chemical industry, food processing, medical technology or building automation. They can be used in liquids as well as in gaseous media or solids.
5. Simple installation: Sheath temperature sensors are relatively easy to install and connect to various systems. They are available in different sizes and designs to meet individual requirements.
Overall, sheath temperature sensors offer reliable and precise temperature measurement in demanding environments and are therefore a popular choice in many industrial sectors.
How accurate are sheath temperature sensors in measuring temperatures?
Sheath temperature sensors are generally very accurate in measuring temperatures. They consist of a metal sheath that protects and insulates the sensitive parts of the sensor. The sensor itself consists of a thermocouple or a resistance thermometer, both of which enable very precise measurements.
The thermocouple uses the so-called Seebeck effect, in which a voltage is generated when two different metals are connected at one end and exposed to different temperatures at the other ends. This voltage is proportional to the temperature difference and enables accurate temperature measurement.
A resistance thermometer is based on the principle that the electrical resistance of a metal changes with increasing temperature. The temperature can be precisely determined by measuring the resistance.
Sheath temperature sensors offer high accuracy and are able to detect temperature changes quickly and precisely. They are used in many applications, including industrial processes, air conditioning systems, vehicles and other areas where accurate temperature measurements are required.
The thermocouple uses the so-called Seebeck effect, in which a voltage is generated when two different metals are connected at one end and exposed to different temperatures at the other ends. This voltage is proportional to the temperature difference and enables accurate temperature measurement.
A resistance thermometer is based on the principle that the electrical resistance of a metal changes with increasing temperature. The temperature can be precisely determined by measuring the resistance.
Sheath temperature sensors offer high accuracy and are able to detect temperature changes quickly and precisely. They are used in many applications, including industrial processes, air conditioning systems, vehicles and other areas where accurate temperature measurements are required.
Which areas of application are particularly suitable for sheath temperature sensors?
Sheathed temperature sensors are particularly suitable for applications where accurate and reliable temperature measurement is required. Some of the most common areas of application are
1. Industrial process monitoring: Sheathed temperature sensors can be used in industrial plants to monitor the temperature in various processes, e.g. in the chemical, food, pharmaceutical or oil and gas industries.
2. Heating, ventilation and air conditioning technology: Sheathed temperature sensors can be used in heating, ventilation and air conditioning systems to monitor and control the room temperature.
3. Motor temperature monitoring: Sheath temperature sensors can be used in motors to monitor the temperature of the motor and protect it from overheating.
4. heat exchanger: Jacket temperature sensors can be used in heat exchangers to monitor the temperature of the medium and optimize the efficiency of the heat exchange.
5. Food and beverage industry: Sheathed temperature sensors are often used in the food and beverage industry to monitor the temperature of food, beverages and refrigerators or freezers.
6. Building automation: Sheathed temperature sensors can be used in building automation and energy management systems to monitor and control the temperature in various areas of a building.
There are many other areas in which sheath temperature sensors can be used, depending on the specific requirements and needs of the application.
1. Industrial process monitoring: Sheathed temperature sensors can be used in industrial plants to monitor the temperature in various processes, e.g. in the chemical, food, pharmaceutical or oil and gas industries.
2. Heating, ventilation and air conditioning technology: Sheathed temperature sensors can be used in heating, ventilation and air conditioning systems to monitor and control the room temperature.
3. Motor temperature monitoring: Sheath temperature sensors can be used in motors to monitor the temperature of the motor and protect it from overheating.
4. heat exchanger: Jacket temperature sensors can be used in heat exchangers to monitor the temperature of the medium and optimize the efficiency of the heat exchange.
5. Food and beverage industry: Sheathed temperature sensors are often used in the food and beverage industry to monitor the temperature of food, beverages and refrigerators or freezers.
6. Building automation: Sheathed temperature sensors can be used in building automation and energy management systems to monitor and control the temperature in various areas of a building.
There are many other areas in which sheath temperature sensors can be used, depending on the specific requirements and needs of the application.
What factors influence the accuracy and reliability of a sheath temperature sensor?
There are various factors that can influence the accuracy and reliability of a sheath temperature sensor:
1. Calibration: Regular calibration of the temperature sensor is crucial to ensure that it provides accurate readings. Incorrect calibration can lead to incorrect measurements.
2. Material of the coat: The sheath of the temperature sensor should be made of a material with good thermal conductivity in order to measure the temperature accurately. The wrong material can lead to inaccurate measurements.
3. Heat dissipation: The temperature sensor should be able to dissipate heat efficiently to the environment to enable accurate measurements. Insufficient heat dissipation can lead to overheating of the sensor and impair the measurements.
4. Environmental influences: The environment in which the temperature sensor is used can influence the measuring accuracy. Factors such as air currents, vibrations or electromagnetic interference can lead to measurement errors.
5. Cabling: The wiring of the temperature sensor should be correct and well shielded to minimize interference. Incorrect cabling can lead to inaccurate measurements.
6. Aging: A temperature sensor can lose accuracy over time. It is important to carry out regular checks and, if necessary, replace the sensor to ensure reliable measurement.
7. Measurement range: The measuring range of the sensor should meet the requirements of the application. Overloading the sensor can lead to inaccurate measurements.
8. Installation situation: The temperature sensor should be correctly installed in the medium to be measured. An incorrect installation situation, such as an insufficient contact surface or uneven heat transfer, can lead to inaccurate measurements.
1. Calibration: Regular calibration of the temperature sensor is crucial to ensure that it provides accurate readings. Incorrect calibration can lead to incorrect measurements.
2. Material of the coat: The sheath of the temperature sensor should be made of a material with good thermal conductivity in order to measure the temperature accurately. The wrong material can lead to inaccurate measurements.
3. Heat dissipation: The temperature sensor should be able to dissipate heat efficiently to the environment to enable accurate measurements. Insufficient heat dissipation can lead to overheating of the sensor and impair the measurements.
4. Environmental influences: The environment in which the temperature sensor is used can influence the measuring accuracy. Factors such as air currents, vibrations or electromagnetic interference can lead to measurement errors.
5. Cabling: The wiring of the temperature sensor should be correct and well shielded to minimize interference. Incorrect cabling can lead to inaccurate measurements.
6. Aging: A temperature sensor can lose accuracy over time. It is important to carry out regular checks and, if necessary, replace the sensor to ensure reliable measurement.
7. Measurement range: The measuring range of the sensor should meet the requirements of the application. Overloading the sensor can lead to inaccurate measurements.
8. Installation situation: The temperature sensor should be correctly installed in the medium to be measured. An incorrect installation situation, such as an insufficient contact surface or uneven heat transfer, can lead to inaccurate measurements.