In the past few decades, fields such as cell biology, molecular biology, pharmacology, and more have made significant progress. CO2 incubators have become a commonly used laboratory instrument and have found wide applications in research and production in areas including medicine, immunology, genetics, microbiology, agricultural science, and pharmacology.
Jiupo Biology keeps pace with these advancements and continually innovates its technology to enhance the functionality and operation of CO2 incubators. The company focuses on making CO2 incubators safer, more reliable, intelligent, and cost-effective. By providing long-term stability in temperature, CO2 concentration, and humidity during experiments, Jiupo Biology offers comprehensive protection for various cell culture experiments in these fields.
Our CO2 incubators feature a unique patented box cold break structure. The inner chamber and the incubator body are separated, and when the incubator door is closed, it makes contact with the sealing gasket but does not directly touch the inner chamber. This design reduces the rate of heat transfer, allowing for a cold break. The use of electrically insulating materials for the limit block and L-shaped limit block further minimizes heat transfer, resulting in energy savings. This innovative design helps maintain temperature stability and reduces energy consumption, providing a more efficient and cost-effective solution for your research needs.
Our CO2 incubators feature a patented built-in door and window technology with double-layer tempered glass windows. This unique and aesthetically pleasing design not only enhances the incubator's insulation performance and reduces temperature fluctuations but also minimizes condensation overflow when the door is opened. Even when you open the observation window, the interior chamber remains in a sealed state, eliminating the need to stop operations. This feature prevents temperature and CO2 concentration fluctuations and external contamination, ensuring a stable and controlled environment for your experiments.
The internal structure of the chamber is characterized by a simplified design, consisting of just four components: stainless steel shelves, suspended backplate, HEPA filter, and a top airflow guide structure. These components can be easily and quickly disassembled without the need for tools, and there's no requirement to disassemble any electrical components. This streamlined design simplifies maintenance and ensures efficient and hassle-free operation.
During one-button high-temperature sterilization, the external heat insulation protection device for the CO2 sensor can be activated without needing to disassemble the sensor. This approach serves a dual purpose: it protects the CO2 sensor from high temperatures during sterilization and prevents secondary contamination during sensor reinstallation after sterilization. This innovative feature ensures the safety and integrity of the CO2 sensor and the reliability of your experiments.
Our CO2 incubators feature a patented circulating airflow design. In this system, air is drawn in from the top of the front end of the internal chamber, passing through a HEPA filter, and guided by the descending airflow structure. It is then propelled by an upstream fan to the rear airflow duct and evenly distributed through the perforated rear panel. This circulation structure ensures uniform temperature, humidity, and CO2 concentration across all corners of the incubator. Additionally, it continuously filters and purifies the air within the chamber, creating a controlled and clean environment for your experiments.
Our CO2 incubators are equipped with an intelligent PID control system for precise temperature and CO2 concentration control. This system offers high accuracy and is complemented by an intuitive touchscreen human-machine interface for easy and user-friendly operation. Additionally, an integrated independent temperature protection control circuit is built in, and high-temperature sterilization is employed for added safety and control during operation. This intelligent and precise control system ensures the reliability and stability of your experiments.
1 During high-temperature sterilization, the external heat insulation device for the carbon dioxide sensor effectively provides thermal insulation. It reduces the transfer of heat from the incubator's interior to the carbon dioxide sensor, preventing potential damage to the sensor. This feature ensures the longevity and accuracy of the carbon dioxide measurements in the incubator.
2 During the periodic sterilization process in the CO2 incubator, it is capable of achieving high-temperature sterilization at 120°C without the need to remove the carbon dioxide sensor. This feature ensures that there is no risk of secondary contamination when conducting sterilization, preserving the sterility and integrity of the incubator's interior environment.
3 The CO2 incubator features an efficient air circulation system. Fresh air is drawn in from the top of the front-facing filter chamber. It then flows from the lower chamber of the intake duct to the upper chamber and is evenly propelled to the rear circulation chamber by an axial flow fan. From there, it is distributed forward, creating a continuous and well-distributed airflow circulation throughout the incubator. This design ensures excellent airflow dynamics and uniformity, maintaining a controlled and consistent environment for your experiments.
4 The filter chamber is equipped with filtration devices to effectively filter the air inside the incubator, ensuring air quality. This feature prevents any negative impact on cell cultures within the incubator due to air quality issues. Furthermore, the filtration devices are designed for easy disassembly, replacement, and cleaning, simplifying maintenance and ensuring a clean and controlled environment for your cell cultures.
5 The inner chamber features curved edges, which prevent the accumulation of dirt and debris, minimizing the growth of microorganisms in the incubator. This design ensures a more efficient cell culture process and facilitates easy cleaning and maintenance.
6 The incubator's door is equipped with a transparent glass window, allowing observation without the need to open the main door of the incubator. This design prevents external air from entering the incubator and affecting the cultured samples, ensuring a stable and controlled internal environment.
7 The cooling fans, circulation fan motor, and electromagnetic control valves are positioned within the control chamber layer but are located outside the incubator body. This setup prevents the heat generated inside the incubator from affecting the performance and operation of the cooling fans, circulation fan motor, and electromagnetic control valves. This design ensures efficient heat dissipation and maintains the stability of the incubator's internal temperature and environmental conditions.
CO2-Incubator-CIC170 | ||
Outer Dimensions (WxDxH) | 720 x 613 x 894mm | |
Inner Dimensions (WxDxH) | 607 x 474 x 682mm | |
Heating Method | Gas-Jacketed | |
Internal Volume | 176L | |
Standard Number of Shelves | 6 | |
Shelf Height | 90mm | |
Water Tray Capacity | 7.5L | |
Temperature Range | Room temperature +5°C to 55°C | |
Temperature Display Resolution | 0.1℃ | |
Temperature Fluctuation [±K] | ±0.3℃(@37℃) | |
Temperature Uniformity [±K] | ±0.5℃(@37℃) | |
CO₂ Sensing Technology | Non-Dispersive Infrared (NDIR) Principle Explosion Protection Level: Exia ⅡC T4 Ga | |
CO₂ Concentration Control Range | Ambient to 20% | |
CO₂ Accuracy | 0-1%vol: ≤±0.06%vol;1-20%vol: ≤±(0.05% + 5% of true value) | |
CO₂ Display Resolution | 0.1% | |
CO₂ Control Deviation | ±0.3% | |
Device Net Weight (Empty) | 90kg | |
Internal Fan Power | 120W | |
Electric Heating Power | 800W | |
Peak Power | 950W | |
Operating Environment Temperature | 5°C to 30°C | |
Operating Voltage and Current | 220VAC / 50Hz | |
Air Filtration Method | HEPA Filtration | |
Disinfection Method | Moist Heat Sterillization (120℃) |