Climate Chamber(plant growth chamber) CMC-B450
Features
- Constructed with corrosion-resistant stainless steel and
powder-coated exterior.
- Double-door system with inner glass door allows observation without
disrupting internal conditions.
- Programmable LED illumination with 8 adjustable levels prevents
light degradation over time.
- Sophisticated dynamic control mimics natural diurnal cycles through
coordinated parameter management.
- Capable of executing complex 30-segment temperature profiles for
research applications.
- Efficient R134a refrigerant-based cooling system operates quietly
with minimal temperature fluctuation.
- 3D uniform heating and adjustable circulated air speed ensure
consistent chamber conditions.
- Fast, accurate humidification controlled by a reliable humidity
sensor.
- User-friendly interface with 99-hour timer, multiple alarms, and
calibration functions.
- Expandable with optional UV sterilization and independent
over-temperature protection.
Specifications
| Model | CMC-B450 |
| Chamber Volume(L) | 450 |
| Temp. Control Range | With illumination: 10℃~ 50℃. Without illumination: 5℃~ 50℃ |
| Temperature | Resolution | 0.1℃ |
| Fluctuation | ± 0.5℃ |
| Uniformity | ± 2℃ at 37℃ |
| Controller | PID microprocessor control, soft touch, LED display |
| Sensor | PT100 |
| Humidity Control Range | 50%~90% |
| Humidity | Resolution | 0.1%RH |
| Fluctuation | ± 5%RH |
| Controller | PID microprocessor control, soft touch, LED display |
| Sensor | Capacitor type |
| Illumination | 0-20000LX |
| Timer | Power-on, power off and working. Timing range: 1min-99hr |
| Material | Internal | Mirror polished 304 stainless steels |
| External | 08F |
| Dimensions (WxDxH,mm) | Internal | 700*650*950 |
| External | 850*910*1730 |
| Net Weight(Kg) | 194 |
| Consumption Power(W) | 2430 |
| Shelf Size(mm) | 634*630 |
| Shelf Qty(Standard/Max.) | 3/13 |
| Power Supply | 220V/50Hz (Optional: 220V/60Hz, 110V/60Hz) |
*Working temperature: 5-30℃. Max. working humidity: 80%RH.
Max.working altitude: 2000m *UV lamp is optional
Introduction about incubator
The future of laboratory incubators lies in connectivity, data
intelligence, and seamless integration into automated workflows.
The Internet of Things (IoT) is transforming stand-alone units into
networked nodes. Smart incubators feature Wi-Fi or Ethernet
connectivity, enabling remote monitoring of conditions
(temperature, CO2, O2, humidity) via smartphone apps or web
dashboards. Researchers receive real-time alerts for deviations,
allowing immediate intervention. This data logging is no longer
simple; it’s comprehensive, time-stamped, and easily exportable for
regulatory compliance (FDA 21 CFR Part 11).
Integration with Laboratory Information Management Systems (LIMS)
allows sample conditions to be automatically recorded alongside
other experimental metadata. Furthermore, incubators are becoming
components in larger automated cell culture systems. Robotic arms
can access these “smart incubators" to feed, passage, or image
cells without breaking containment, enabling high-content screening
and the maintenance of complex organoid or co-culture systems over
weeks with minimal manual intervention.
Predictive analytics based on performance data can forecast sensor
drift or component failure, prompting preemptive maintenance. This
shift from a passive environmental chamber to an active,
intelligent, and connected platform enhances reproducibility,
unlocks new experimental possibilities, and frees researchers from
mundane monitoring tasks.
