Mechanically Stirred Glass Bioreactor NMSGR-101 features a working volume of 1.5 to 3.5 L, enabling flexible operation. This reactor offers precise temperature control from 4 to 60°C for stable processing. Our unit regulates pH using PID control, ensuring accurate acid-base balance. It maintains DO levels from 0 to 150%, supporting optimal aerobic conditions. It uses a mechanical-seal shaft with a 6-blade stirrer for consistent and efficient mixing.
FAQ for Mechanically Stirred Glass Bioreactor NMSGR-101
1: What is the total and working volume of the Mechanically Stirred Glass Bioreactor NMSGR-101?
The Mechanically Stirred Glass Bioreactor NMSGR-101 has a total volume of 5 L and a working volume range of 1.5 to 3.5 L. This allows flexibility for various fermentation and cell culture experiments. Users can optimize culture volumes according to experimental needs.
2: What type of vessel and lid does the bioreactor use?
This reactor uses a durable borosilicate glass vessel with a stainless steel 316L lid. This combination ensures chemical resistance and long-term reliability. Users can safely perform demanding biological reactions without contamination risks.
3: How does the bioreactor ensure efficient mixing?
It uses a mechanical seal shaft with a 6-blade stirrer and a speed range of 30 to 1000 rpm. This ensures uniform mixing and consistent nutrient distribution. Proper agitation supports optimal growth and product formation.
4: What aeration system is included in the NMSGR-101?
The Mechanically Stirred Glass Bioreactor NMSGR-101 uses a ring sparger with sterile filters to deliver controlled aeration. Automatic ventilation and pressure regulation ensure clean and consistent gas flow. This maintains optimal oxygen levels for cell culture and fermentation.
5: Does the Mechanically Stirred Glass Bioreactor support anti-foam and automated feeding?
Yes, the Mechanically Stirred Glass Bioreactor NMSGR-101 includes automatic PID anti-foam control and an automated feeding system. These features ensure stable culture conditions and reduce manual intervention. They improve reproducibility and simplify long-term experiments.
