320x256/30μm Cooled LWIR Detector G330C2 For SF6/NH3 Gas Leak Detection

Product Description:

The G330C2 cooled infrared detector for optical gas imaging (OGI) is a cutting-edge solution for gas leak detection. It transforms long-wavelength infrared radiation into electrical signals, providing accurate and reliable results. Its mechanical, optical, and electronic interfaces are designed for compatibility and scalability, making it adaptable to diverse applications. This detector is widely employed in environmental monitoring, gas leak detection, pollutant emission analysis, and chemical gas detection in petrochemical and refinery operations.

Using advanced T2SL (Type II Superlattice) material, the G330C2 infrared detector offers unparalleled sensitivity and precision in gas detection. The T2SL material ensures optimal performance across a broad spectrum of infrared wavelengths, enabling the detector to identify even minimal gas concentrations. This capability allows for real-time visualization of gas leaks, facilitating prompt assessment and action. 

The G330C2 is ideal for a variety of gas detection scenarios, including sulfur hexafluoride (SF6) and ammonia (NH3) gases detection in industrial applications.

Main Features:

Optical Gas Imaging
• Long range non-contact detection
• High efficient, secure and wide range of gas leak detection

High Sensitivity
• High sensitive cooled infrared detector, quite efficient in application of low gas concentration and slow gas flow
• Effective leak detection includes sulfur hexafluoride (SF6) and ammonia (NH3) gases  

Designed for Requirements of Integrators
• Light weight, low power, long life and high reliability

Technical Parameters:

Applications:

Support and Services:

Our infrared detectors and thermal imaging modules are designed to provide high-quality thermal imaging solutions for a wide range of applications. We offer a range of technical support and services to help you get the most out of your product, including:
· Product training and education
· Technical troubleshooting and support
· Repair and calibration services
· Customized solutions and consulting
Our team of experienced professionals is dedicated to providing you with the highest level of service and support possible. Contact us today to learn more about our product technical support and services.

FAQs:

Q: What is infrared thermal imaging technology?

A: Infrared thermal imaging uses photoelectric technology to detect specific infrared band signals of thermal radiation from objects, converts these signals into images and graphics that can be visually distinguished by humans, and further calculates temperature values. 

Q: What is the wavelength range for infrared thermal imaging?

A: Infrared ray, also known as infrared radiation, is an electromagnetic wave in the infrared wavelength range between visible light and microwave. Thermal infrared imaging typically refers to mid infrared imaging at 3-5μm and far-infrared imaging at 8-12μm. In these bands, the focus is on heat sources, not visible light. The human eye is sensitive to the wavelength range of about 0.4~0.7μm and cannot see longer wavelengths of thermal energy. 

Q: What is the classification of infrared thermal imaging wavebands?

A: Generally speaking, infrared thermal imaging is divided into three bands: short wave, medium wave, and long wave.
Shortwave: wavelength range within 3μm;
Medium wave: wavelength range from 3μm to 5μm;
Long wave: wavelength range from 8μm to 14μm;

Q: What are the applications of infrared detectors and thermal imaging modules?

A: The infrared detectors and thermal imaging modules can be used in a variety of applications such as thermography, security & surveillance, intelligent industry, outdoor night vision observation, machine vision, smart driving, UAVs, and consumer infrared products.

Q: Does infrared thermal imaging emit radiation?

A: Infrared thermal imaging passively receives infrared signals emitted by objects and does not have radiation. As long as an object exceeds absolute zero, an infrared signal will be emitted, which is received by an infrared detector and then converted into a thermal image.