CLS Gas Infrared
CLS Gas Infrared — The Future Of Paintshop
Gas infrared systems use combustion of natural gas, propane, or other fuels to generate infrared radiation. This radiant energy heats objects directly without warming the surrounding air, making it highly efficient for targeted heating applications.
Key Features & Benefits
- Direct Radiant Heating: Transfers heat via IR waves, ideal for large or open spaces.
- Fuel-Based Efficiency: Operates on gas, reducing electrical load and energy costs.
- Fast Response Time: Rapid heat-up and cool-down cycles.
- Low Maintenance: Fewer moving parts compared to electric systems.
- Zoned Heating: Allows selective heating of specific areas.
CLS High Intensity Gas Infrared
A metallic gas infrared burner uses a metal fiber or mesh surface to emit infrared radiation when heated by gas combustion. These burners are designed for high-temperature, flameless heating, offering consistent and energy-efficient performance across industrial applications.
- Metal Fiber Surface: Provides uniform heat distribution and high thermal resistance
- Fuel Compatibility: Operates on LPG, PNG, propane, or butane
- Temperature Range: Can reach up to 950°C depending on design
- Shape Options: Available in curved, rectangular, or custom geometries
- Durability: Unbreakable construction with long operational life
- Rapid Response: Quick heat-up and cool-down cycles (typically 3–4 seconds)
- Low Pressure Operation: Suitable for pressures as low as 0.035 kg/cm²
CLS MW CAT Burner
A catalytic burner generates heat through a chemical reaction called catalytic combustion, where fuel (like natural gas, propane, or hydrogen) reacts with oxygen in the presence of a catalyst—typically platinum or palladium. This reaction occurs at relatively low temperatures, producing infrared heat without an open flame.
- Flameless Operation: Reduces fire hazards and allows use in volatile environment
- Catalyst Materials: Platinum for hydrocarbon fuels; palladium for hydrogen applications
- Temperature Range: Typically between 300°C to 550°C, depending on fuel and catalyst
- Emission Control: Ultra-low NOx, CO, and CH₄ emissions—often <2 ppm
- Compact Design: Enables high power density in small combustion zones
