Illuminated incubator PGC-D1000
Features
- Combines a stainless steel interior with a functional 220V outlet
and a durable powder-coated shell.
- Utilizes dual doors with a toughened glass inner panel for thermal
efficiency and safe viewing.
- State-of-the-art 8-level LED illumination provides stable,
adjustable light without the attenuation of fluorescent lamps.
- Integrated microprocessor allows for the creation of complex
profiles controlling temperature trajectories and light periods.
- Execute precise environmental simulations using the 30-segment
temperature curve programming feature.
- High-reliability compressor system ensures long-lasting,
low-fluctuation cooling performance.
- Omni-directional heating and automated airflow control create a
perfectly homogeneous chamber environment.
- Engineered with a fast CPU controller and a high-precision Pt
sensor for dependable operation.
- User-centric design includes parameter memory, display calibration,
and comprehensive alarm systems.
- Optional independent temperature-limit alarm provides an essential
backup for uninterrupted sample safety.
Specifications
| Model | PGC-D1000 |
| Chamber volume (L) | 1000 |
| Temp. Control Range | Without illumination: 0℃~60℃. With illumination: 10℃~60℃ |
| Temperature | Resolution | 0.1℃ |
| Fluctuation | ± 0.5℃ |
| Uniformity | ± 2℃ |
| Controller | PID microprocessor control, soft touch, LED display |
| Sensor | PT100 |
| Illumination | 0-20000LX | 0-20000LX |
| Timer | Power-on, power off. Timing range: 1min~ 2970hr |
| Material | Internal | 304 stainless steel |
| External | 08F |
| Dimensions (WxDxH,mm) | Internal | 950*900*1150 |
| External | 1000*1150*1980 |
| Net Weight(Kg) | 330 |
| Consumption Power(W) | 3200 |
| Shelf Size(mm) | 880*875 |
| Shelf Qty Standard/Maximum) | 3/18 |
| Power Supply | 220V/50Hz (Optional: 220V/60Hz, 110V/60Hz) |
Introduction about incubator
The application of laboratory incubators extends intriguingly into
materials science and nanotechnology. In the development of
biomaterials, incubators are used to test the biocompatibility and
degradation profiles of new polymers, scaffolds, or implants.
Materials are immersed in simulated body fluids (SBF) and held at
37°C to observe how they interact with a physiological
environment—crucial for designing bone grafts or biodegradable
stents.
In nanobiotechnology, incubators play a role in the biogenic
synthesis of nanoparticles. Certain bacteria, fungi, or plant
extracts can reduce metal ions to form nanoparticles when incubated
at specific temperatures, offering a "green" alternative to
chemical synthesis.
Furthermore, when studying the environmental and health impacts of
engineered nanomaterials, incubators are used to culture cells
(lung, skin) exposed to nanoparticles, assessing cytotoxicity and
inflammatory responses under body-mimicking conditions. This
cross-disciplinary use highlights the incubator's role as a
universal platform for maintaining a constant, biologically
relevant temperature, enabling researchers at the interface of
biology and materials to conduct standardized, reproducible safety
and efficacy testing.
