TheΒ roughing pumpΒ is the component that primes the other pumps in series on the vacuum line, evacuating the system until a pressure level is reached at which aΒ booster pumpΒ (known as aΒ lobe-type roots pump) can be activated, followed by other types of diffusion, turbo molecular, cryogenic, ionic andRead more
TheΒ roughing pumpΒ is the component that primes the other pumps in series on the vacuum line, evacuating the system until a pressure level is reached at which aΒ booster pumpΒ (known as aΒ lobe-type roots pump) can be activated, followed by other types of diffusion, turbo molecular, cryogenic, ionic and other pumps that can be used when the pressure is reached.
Depending on the flow rate, the pumping system is proportioned in relation to system volume, pumping cycle speed, load degassing and contamination produced by the load (vapors, dust, binders, etc.) in the pump itself. It is for this reason thatΒ mechanical strength and wearΒ influence the choice of pump type.
I highly recommend you to read an intersting article (splitted in two parts) about this topic:
Roughing pump in high-vacuum furnaces for beginners [1/2]
Roughing pump in high-vacuum furnaces for beginners [2/2]
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Using the roughing pump to evacuate the vacuum chamber before opening the high vacuum (gate) valve is necessary for several reasons related to vacuum efficiency, protection of equipment, and process integrity: 1. Prevent Overloading the High-Vacuum Pump: High-vacuum pumps, such as turbomolecular orRead more
Using the roughing pump to evacuate the vacuum chamber before opening the high vacuum (gate) valve is necessary for several reasons related to vacuum efficiency, protection of equipment, and process integrity:
1. Prevent Overloading the High-Vacuum Pump:
High-vacuum pumps, such as turbomolecular or diffusion pumps, are designed to operate at low pressures and cannot handle atmospheric pressure or high-pressure environments. Starting with a high chamber pressure could overload the pump, potentially damaging it or drastically reducing its performance.
2. Maintain Efficiency and Vacuum Quality:
Roughing pumps (often rotary vane or scroll pumps) are built to handle the initial high pressures in the chamber and can quickly reduce the pressure to a level that high-vacuum pumps can manage efficiently. By using the roughing pump first, the chamber pressure is lowered to a point where the high-vacuum pump can operate effectively without being exposed to excessive gas load.
3. Protect Sensitive Pump Components:
High-vacuum pumps contain delicate, high-speed components (like rotor blades in turbomolecular pumps) that are susceptible to damage or wear if exposed to higher pressures. Bringing the chamber down to a low enough pressure with the roughing pump minimizes the stress on these sensitive components, extending their lifespan and reducing the risk of failure.
4. Minimize Backstreaming and Contamination:
If the high-vacuum pump is started with the chamber at a high pressure, thereβs a greater likelihood of oil backstreaming in oil-sealed systems (e.g., diffusion pumps). Starting with a roughing pump allows a controlled transition to a lower pressure, where the high-vacuum pump can operate without excessive backstreaming risk.
5. Ensure Process Stability and Product Quality:
For processes that require stable, high-purity vacuum levels (such as heat treating, coating, or etching), gradual evacuation through the roughing stage reduces contaminants and moisture in the chamber. This provides a cleaner start for the high-vacuum pump, leading to more consistent and reliable results.
In summary, using the roughing pump first lowers the pressure safely and efficiently, protects the high-vacuum pump from overload, and maintains vacuum quality, which is essential for the performance and longevity of the vacuum system.
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