Nitrogen Generator for Fire Sprinkler Pipe Systems

Introduction to Nitrogen Generators for Fire Sprinkler Pipeline Systems

Nitrogen generators are widely used in industrial applications and are also suitable for fire protection systems. The nitrogen produced by nitrogen generators possesses unique chemical properties—it is an inert gas with low reactivity, making it less likely to react with open flames. This allows it to effectively suppress fires, making it highly useful for firefighting purposes. In fire protection systems, nitrogen produced by nitrogen generators can be applied in nitrogen fire extinguishers, nitrogen-based fire suppression systems, and fire sprinkler pipeline systems with significant effectiveness.

Nitrogen generators play a critical role in fire sprinkler pipeline systems. Integrating sprinkler facilities with nitrogen generators primarily serves to replace oxygen in the water sprinkler system with nitrogen, thereby delaying corrosion and significantly extending the equipment's lifespan.

The nitrogen produced by nitrogen generators offers several additional benefits in water sprinkler pipeline systems. It reduces equipment maintenance needs—using nitrogen from nitrogen generators in fire sprinkler systems can reduce corrosion by up to 98%. Moreover, nitrogen is more affordable and easier to obtain compared to other rare gases, helping enterprises lower costs considerably.

Working Process of Nitrogen Generators for Fire Sprinkler Pipeline Systems

1. Air Intake: The air compressor forces air at a certain pressure into the delivery pipeline. The compressed air then passes through a purification system to remove moisture, oil, dust, and other impurities before reaching the air buffer tank. From there, it is delivered to two adsorption towers.

2. Adsorption: When air enters the adsorption towers, oxygen and carbon dioxide are rapidly adsorbed under pressure. Nitrogen becomes enriched near the gas outlet inside the tower.

3. Gas Output: When the adsorption process reaches the point where nitrogen has the lowest adsorption affinity for oxygen, the gas output valve opens, releasing the finished nitrogen into the nitrogen buffer tank.

4. Pressure Equalization: After the exhaust process is completed, a certain pressure and purity of nitrogen-gas mixture remain in the tower. Rather than wasting it, this mixture is directly discharged into the other adsorption tower to undergo re-adsorption along with the incoming air. This process ends when the pressures in both towers equalize, hence it is called pressure equalization.

5. Exhaust: After pressure equalization, the gases adsorbed by the molecular sieve in the tower need to be released to prepare for the next adsorption cycle. The program automatically opens the exhaust valve, returning the tower’s pressure to its initial state and expelling all adsorbed gases, allowing the molecular sieve to regain its ability to adsorb new air.

6. By alternating the operation of the two adsorption towers, a continuous supply of 99.99% pure nitrogen can be generated to meet demand.