Lysine
1. Material Overview
Lysine is one of the essential amino acids for the human body, promoting human development, enhancing immune function, and improving the function of the central nervous system. In food applications, lysine is mainly used as a flavor enhancer in milk powder, in children's health products, and as a nutritional supplement. Lysine can also be used as a flavoring agent in alcoholic beverages, soft drinks, bread, and starch-based products.
2. Process Introduction
Lysine sulphate slurry from the slurry tank is filtered by slurry filter, then it is pressurized by slurry pump before entering the top nozzle of the fluid bed dryer for granulation. Inside the dryer, the slurry atomized by compressed air is sprayed onto the granules, then it undergoes heat and mass exchange with hot air and internal coil inside the dryer, resulting in temperature increase and moisture removal.
Pre-dried granule product reaching the particle size requirements is fed into the drying/cooling fluid bed dryer through the feeding valve. After drying and cooling process, the final product is discharged from the dryer outlet through the discharge valve.
3. Technical Advantages
The tubular heat exchanger is provided inside the dryer to be immersed around by the feedstock, and the drying system adopts dual heating mechanism combining conductive heat transfer and hot air convection. Heat transfer medium flows through the internal heat exchanger; 80% of the heat is provided by the internal heat exchange tubes, and 20% by hot air.
This internal heating method provides the main heat, significantly reducing the amount of hot air required for fluidization. It not only reduces the power consumption of the fan but also minimizes heat loss from exhaust emissions, further improving the overall energy efficiency of the drying system. Therefore, system can reduce 30% consumption in thermal energy.
(1) Key Components
a. Immersed heat exchanger layout
Multiple heat exchange tube bundles are evenly arranged in bottom part of the fluid bed dryer, maximizing the heat transfer area and ensuring full contact between the fluidized material and the tube bundle surface, thus enhancing heat transfer efficiency.
b. Slide rail extraction design of heat exchange tube bundle
The core heat exchange tube bundle is integrated with a slide rail device, allowing it to be completely extracted from the equipment for thorough cleaning, inspection, and replacement, significantly reducing maintenance downtime.
c. Air distribution plate
The air distribution plate adopts the patented three-layer side-blowing structure, with polished surfaces in contact with the feedstock. The unique design and reasonable distribution of the air distribution plate ensure that the minimum wind speed at all points within the material layer is not lower than its settling velocity. Uniform air pressure distribution inside the dryer can ensure the evenly mixing of the material with no dead zones, ensuring sufficient mass and heat transfer between the material and internal heat exchange tube bundles.
(2) Control
a. Automated program control
Integrating complete PLC control logic, it can realize fully automated operation from feeding, drying to discharging, and supports preset and automatic switching of multiple drying process parameters.
b. Precise parameter real-time monitoring
Real-time acquisition and display of key process parameters such as material layer temperature, heat medium temperature, flow rate, feeding rate, and system pressure difference. Temperature control accuracy can reach ±2℃, ensuring a stable and controllable drying process.
(3) Standardized exhaust gas emission control measures
a. Enlarged upper part settling design
The upper part of the dryer adopts an enlarged section structure to reduce airflow velocity, promote natural settling of particles, significantly reduce the amount of dust entrained with the exhaust gas, and reduce the load on the subsequent dust removal system.
b. Cyclone and bag filter dust removal system
Equipped with cyclone for primary coarse separation, followed by the bag filter for fine separation, the recovery rate of fine powder with a particle size <100μm reaches over 95%, ensuring high material recovery rate and meeting environmental emission standards.
c. Low operating velocity and patented air distribution plate design
Combination of low fluidization operating velocity and special air distribution plate can reduce the entrainment of dust particles, controlling dust generation and material loss at the beginning.
4. Technical Benefit
(1) Small footprint
Due to the significant reduction in air volume, the material layer area of dryer requires only half of the ordinary dryer equipment, resulting in substantial reduction in footprint. This allows for greater flexibility in workshop layout, and facilitates future capacity adjustments as well as the upgradation of production line. Equipment and civil works investments are significantly reduced, and exhaust gas treatment system only requires less investment due to its small equipment size.
(2) Significantly reduced steam consumption
The system utilizes built-in high-efficiency heat exchange tubes to ensure that the main heat is provided by conduction, resulting in low operating energy consumption and low costs.
Taking 8.5 t/h capacity as example, steam consumption is only 6.5 t/h (0.5 MPa), far lower than conventional hot air drying methods.
(3) Significantly optimized power consumption
Thanks to the internal heating technology, system power consumption is significantly reduced by less dependence on large amounts of hot air.
For the specific capacity mentioned above, the installed power is only 1219 kW, effectively reducing electricity costs during production compared to conventional drying equipment.
(4) High product quality
The parts come into contact with materials are made of stainless steel and polished to reduce material residue and adhesion within the equipment, preventing the introduction of impurities caused by equipment and ensuring product purity.