A Pirani gauge is a thermal conductivity vacuum gauge used to measure low to medium vacuum levels, generally from about 0.5 Torr down to 10β»β΄ Torr. Its operation is based on the principle that the thermal conductivity of gases changes with pressure. Working Principle 1. Heating Element: The gauge coRead more
A Pirani gauge is a thermal conductivity vacuum gauge used to measure low to medium vacuum levels, generally from about 0.5 Torr down to 10β»β΄ Torr. Its operation is based on the principle that the thermal conductivity of gases changes with pressure.
Working Principle
1. Heating Element: The gauge consists of a thin filament, usually made of tungsten or platinum, which is heated by a constant electric current. When the filament is in a vacuum, the heat dissipates through conduction to the surrounding gas molecules.
2. Thermal Conductivity: As gas pressure decreases, fewer gas molecules collide with the filament, resulting in less heat being conducted away. At higher pressures, more gas molecules are present, leading to more efficient heat transfer.
3. Measuring Resistance Change: As the filament heats up, its electrical resistance changes. This resistance variation is measured and correlated to the gas pressure. When the vacuum level is high (fewer gas molecules), the filament stays hotter, leading to higher resistance. When the pressure is higher, the filament cools more due to increased molecular collisions, leading to lower resistance.
4. Calibration: The gauge is calibrated to translate this resistance into a pressure reading. Pirani gauges are generally calibrated for specific gases (usually air or nitrogen), so the accuracy can vary with different gases due to differences in thermal conductivity.
Applications and Limitations
- Applications: Pirani gauges are commonly used in vacuum systems that operate in the low to medium vacuum range, such as in vacuum furnaces, coating processes, and other industrial applications.
- Limitations: The accuracy of a Pirani gauge can be affected by changes in gas composition, as different gases have different thermal conductivities. Additionally, they are less effective at very high vacuums (e.g., below 10β»β΄ Torr), where other types of gauges like ionization gauges are preferred.
An ion vacuum gauge measures extremely low pressures (high vacuum) by ionizing gas molecules within the gauge and detecting the resulting ions. This type of gauge is commonly used in high and ultra-high vacuum systems, capable of measuring pressures down to 10β»ΒΉβ° Torr or lower. Working Principle 1.Read more
An ion vacuum gauge measures extremely low pressures (high vacuum) by ionizing gas molecules within the gauge and detecting the resulting ions. This type of gauge is commonly used in high and ultra-high vacuum systems, capable of measuring pressures down to 10β»ΒΉβ° Torr or lower.
Working Principle
1. Electron Emission: The ion gauge contains a hot filament, typically made of tungsten or another refractory metal, which emits electrons when heated. These electrons are accelerated into the gauge by an applied voltage.
2. Ionization of Gas Molecules: As the emitted electrons move through the gauge, they collide with gas molecules present in the vacuum chamber, ionizing them. This process creates positively charged ions from neutral gas molecules.
3. Ion Collection: The positive ions are attracted to a collector electrode (a wire or a plate) maintained at a negative potential. When these ions strike the collector, they generate a small current.
4. Current Measurement: The ion current is directly proportional to the density of gas molecules in the vacuum, and hence to the pressure. By measuring the ion current, the gauge provides a reading of the pressure in the chamber.
Types of Ion Gauges
The most common types of ion vacuum gauges are:
Key Components
Applications and Limitations
Advantages
In summary, ion vacuum gauges operate by ionizing gas molecules in the vacuum and measuring the resulting ion current, providing precise pressure readings in high and ultra-high vacuum ranges.
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