 |
| Quantity: | |
|---|---|
Jet Loop Reactors are high-efficiency reaction equipment widely used in gas-liquid two-phase and gas-liquid-solid three-phase reactions. By utilizing the entrainment effect of high-speed mobile phases, they achieve intimate contact and uniform dispersion of multiple phases, making them an ideal choice for chemical, pharmaceutical, and environmental protection industries pursuing high reaction efficiency and low energy consumption.
The unique jet structure enhances the mass transfer coefficient between phases, increasing reaction efficiency by 30-50% compared with traditional reactors. The high-speed fluid flow eliminates local concentration gradients, ensuring full reaction of materials.
The integrated design reduces the equipment footprint by 20-30% without compromising performance. Key components are made of 304/316L stainless steel or corrosion-resistant alloys, with strong resistance to acid, alkali, and high temperature, extending service life.
It can handle both gas-liquid two-phase reactions (such as oxidation and hydrogenation) and gas-liquid-solid three-phase reactions containing catalysts or suspended particles. The adjustable jet speed allows adaptation to different reaction systems and process requirements.
The reactor relies on the jet entrainment effect to realize mixing and reaction, reducing energy consumption by 25-40% compared with mechanical stirring reactors. The simple structure simplifies operation and maintenance, requiring no complex training for operators.
The global jet loop reactor market is expected to reach $1.2 billion by 2027, with a CAGR of 6.2%. Driven by the demand for green production in the chemical and pharmaceutical industries, and the promotion of energy-saving policies, the market is shifting towards high-efficiency, low-pollution equipment. Asia-Pacific is the fastest-growing region, led by China, India, and Southeast Asian countries, due to the expansion of chemical parks and environmental protection upgrades.
The reactor complies with ASME pressure vessel standards and ASTM material specifications. Its leakage rate is less than 1×10⁻⁶ Pa·m³/s, meeting the strict safety requirements of industrial production. The mass transfer efficiency and reaction conversion rate exceed industry averages, ensuring that products meet the quality standards of fine chemicals and pharmaceutical intermediates.
Used in oxidation, hydrogenation, esterification, and polymerization reactions, suitable for producing dyes, pigments, and fine chemical intermediates.
Applied in drug synthesis, fermentation, and enzyme-catalyzed reactions, ensuring gentle reaction conditions and high product purity.
Used in wastewater treatment (such as catalytic oxidation of organic pollutants) and flue gas desulfurization/denitrification, improving pollutant removal efficiency.
Applicable to hydrogen production by water electrolysis, CO₂ hydrogenation, and other reactions, supporting the development of clean energy.
The reactor is suitable for solid catalysts with particle sizes of 1-100 μm, including powder, granular, and supported catalysts. It can avoid catalyst agglomeration through reasonable jet speed adjustment.
The optimized jet nozzle design and internal flow channel structure ensure uniform phase distribution. If uneven distribution occurs, adjusting the jet speed or installing a flow baffle (provided as an optional accessory) can effectively improve the situation.
Yes. We provide scalable solutions from laboratory-scale (50 L) to industrial-scale (50 m³). The scaling process is supported by numerical simulation and pilot test data to ensure consistent performance between small and large equipment.
