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Overview
Thin Film Evaporator LMTFE-A104 is designed with feeding rate of 0.5 to 15 L/h. It builds from high grade glass to ensure corrosion resistance and effortless cleaning. Equipped with scraper film, it allows efficient material contact and processing. Incorporating full jacket insulation, it enables even substance flow. Our Evaporator is ideal for separation of chemicals, essential oils, and heat-sensitive compounds.
Features :
Fewer interface points
Magnetic coupling seal
Leak prevention
Real-time vacuum readings
Multi-plan structure
Adjustable process parameters
Intuitive monitoring
Specifications :
| Feeding Rate | 0.5 to 15 L/h |
| Feeding Flask Volume | 3 L |
| Operating Temperature | Less than 300°C |
| Rotation Speed Range | 50 to 450 rpm |
| Material | Borosilicate 3.3 |
| Evaporation Area | 0.35 m2 |
| Internal Condenser Area | 0.42 m2 |
| Power Supply | 220V/50Hz,1P |
| Dimensions | 2250×610×2400 mm |
Applications :
Thin Film Evaporator LMTFE-A104 ensures separation, purification, and concentration of pharmaceuticals, chemicals, essential oils, food extracts, and heat-sensitive materials in research, development, and industries.
Selection Guide :
Thin Film Evaporator LMTFE-A104 is best suited for applications requiring efficient thermal separation under vacuum conditions, particularly in the chemical, pharmaceutical, food, and petrochemical industries. Based on research studies, this model is frequently used in experiments involving heat-sensitive and high-viscosity substances, such as essential oil recovery, solvent distillation, resin and polymer concentration, and purification of natural extracts. It supports continuous operation with a high evaporation rate and reduced residence time, which helps preserve product integrity. It is certified to meet international safety and quality standards (such as ISO and CE), ensuring reliable performance and regulatory compliance. Customers seeking a system that provides advanced process control, uniform film distribution, and excellent heat transfer efficiency will find this model suitable for both pilot-scale research and industrial processing applications.
