Electric heating reactor

Electric heating reactorisThe structure, function, and accessories of the reactor were designed based on the reaction conditions. From the beginning, the feed reaction discharge can be highly automated to complete the pre-set reaction steps, and important parameters such as temperature, pressure, mechanical control (stirring, blowing, etc.), and reactant/product concentration during the reaction process can be strictly controlled. The structure of this utility model generally consists of a kettle body, a transmission device, a mixing device, a heating device, a cooling device, and a sealing device. Corresponding auxiliary equipment: fractionation tower, condenser, water separator, collection tank, filter, etc.

Reactor materials generally include composite materials such as carbon manganese steel, stainless steel, zirconium, nickel based (Harrington, Monel) alloys, etc. The reactor can be made of stainless steel such as SUS304 and SUS316L, and the agitator can be anchored, framed, propeller, turbine, scraper, or combination. The rotating mechanism can adopt cycloidal pinwheel reducer, continuously variable transmission or variable frequency speed regulation, etc., which can meet the special response requirements of various materials. The sealing device can adopt sealing structures such as mechanical seals and packing seals. Heating and cooling can be achieved through structures such as jackets, half tubes, coils, grinding discs, etc. Heating methods include steam heating, electric heating, and thermal oil heating to meet the process requirements of different working environments such as acidity, high temperature, wear resistance, and corrosion resistance. It can also be designed and manufactured according to the user's process requirements.

Electric heating reactorThe structure, function, and accessories of the reactor were designed based on the reaction conditions. From the beginning, the feed reaction discharge can be highly automated to complete the pre-set reaction steps, and important parameters such as temperature, pressure, mechanical control (stirring, blowing, etc.), and reactant/product concentration during the reaction process can be strictly controlled. The structure of this utility model generally consists of a kettle body, a transmission device, a mixing device, a heating device, a cooling device, and a sealing device. Corresponding auxiliary equipment: fractionation tower, condenser, water separator, collection tank, filter, etc.

Reactor materials generally include composite materials such as carbon manganese steel, stainless steel, zirconium, nickel based (Harrington, Monel) alloys, etc. The reactor can be made of stainless steel such as SUS304 and SUS316L, and the agitator can be anchored, framed, propeller, turbine, scraper, or combination. The rotating mechanism can adopt cycloidal pinwheel reducer, continuously variable transmission or variable frequency speed regulation, etc., which can meet the special response requirements of various materials. The sealing device can adopt sealing structures such as mechanical seals and packing seals. Heating and cooling can be achieved through structures such as jackets, half tubes, coils, grinding discs, etc. Heating methods include steam heating, electric heating, and thermal oil heating to meet the process requirements of different working environments such as acidity, high temperature, wear resistance, and corrosion resistance. It can also be designed and manufactured according to the user's process requirements.