TH2201006985A - NYLON 6 PRODUCTION PROCESS, SYSTEM, AND PRODUCT - Google Patents

Abstract

This application concerns the textile raw materials field and specifically provides a nylon 6 production process system, and the nylon 6 production process product comprises the following steps: caprolactam, water, molecular weight control agent, benzylamine and coating agent are used as reaction raw materials and are heated to prepare for entering the polymerization process. The polymerization reaction is a two-step polymerization process in which the pressure is first pressurized and then depressurized, and the solution generated in the depressurization process is passed into the pressure polymerization process, pelleted, the product after polymerization is extracted, the water after pelleting is evaporated and the solution after extraction is passed into the pressure polymerization step. The existing problem in the work that when nylon 6 is produced using the two-step polymerization method, a large amount of moisture is generated in the post-polymerization step, resulting in the need for multiple extraction towers to perform multiple extraction steps, low extraction efficiency and waste of heat source is solved.

Claims (10)

1. Nylon 6 production technology, which consists of the following steps: 1) heating the raw materials, which include caprolactam, water, molecular weight modifier, benzylamine and degumming agent, to obtain a fluid mixture; 2) controlling the heated fluid mixture into the polymerization section, where the polymerization reaction is a two-step polymerization, which consists of pressure polymerization and pressure reduction polymerization in sequence, where the solution is continuously produced during the pressure reduction polymerization step and fed into the pressure polymerization step; and 3) pelleting the product after the pressure reduction polymerization step, performing a single-tower extraction, and feeding the solution after extraction into the pressure polymerization step, where the particles in the solid phase after extraction are nylon. 2. The technology for manufacturing nylon 6 according to claim 1, wherein the molecular weight modifier is acetic acid and the degumming agent is titanium dioxide. 3. The technology for producing nylon 6 according to claim 1, wherein the extraction is a single-step extraction and the nylon 6 after extraction is cut into sheets and dried and then exported. 4. The technology for manufacturing nylon 6 according to claim 1, wherein in step 1) caprolactam is introduced into a melting reaction pot to make the melt and during the melting process a mixture of water, molecular weight modifier, benzylamine and a deglosser is added successively until the melt forms a fluid mixture. 5. The technology for manufacturing nylon 6 according to claim 1, wherein in step 2) the pressurized polymerization comprises: delivering the fluid mixture to the polymerization section for the pressurized polymerization, the pressurized polymerization section is divided into an upper and a lower section, the pressurized ring opening, the pressurized mainly acts on the upper section and the pressurized polymerization reaction is performed on the lower section. Ideally, the heat required for the ring opening by the hydrolysis reaction is obtained from the latent heat of liquefaction of the biphenyl biphenyl ether in the vapor phase at 260°C. The heat released by the pressurized polymerization reaction in the lower section is removed by liquefaction of the biphenyl biphenyl ether in the vapor phase at 260°C. Ideally, the pressurized ring opening pressure is 0.150.2 MPa. Ideally, the ring opening reaction time of the compound is 5055 min. Ideally, the pressurized polymerization reaction time of the material is 2.5-4.5 hours. 6. The technology for manufacturing nylon 6 according to claim 1, wherein in step 2) the pressure polymerization comprises: delivering the product from the pressure polymerization to the center of the pressure polymerization reactor for the pressure polymerization to be carried out; the pressure polymerization reaction is a condensation reaction; the water produced during the pressure polymerization is discharged from the top of the pressure polymerization reactor and fed into the pressure polymerization reactor for continuous reaction; ideally, the dehydration in the pressure polymerization is carried out in a vacuum at negative pressure; ideally, the condensation reaction time of the product is 2.53 hours. 7. The nylon 6 production technology of claim 1, wherein the extraction section uses steam as a power source, preferably 1.0 MPa steam, preferably 1.0 MPa steam is used as a heat medium in the first stage of the three-stage evaporation, the water obtained from the first stage evaporation is used as a heat medium for the second stage evaporation, the steam obtained from the second stage evaporation is used as a heat medium for the third stage evaporation, the gas phase obtained after the gas-liquid separation in the exhaust gas from the third stage evaporation is used to heat up the extracted water, the condensate liquid is used to heat up the fresh caprolactam raw material, and a ferrous sulfide crystal cooler is prepared in the ferrous sulfide plant. 8. A system for implementing the nylon 6 production technology according to any one of claims 1 to 7, comprising a pressure polymerizer, a pressure polymerizer, a pelletizer and an extraction tower connected in sequence, wherein an outlet at the top of the extraction tower is connected to an evaporation device and an outlet at the bottom is connected to a packaging section through a gas phase conveying pipe, and the solution discharged from the pressure polymerizer is also fed into the evaporation device. 9. The nylon 6 production technology system of claim 8, wherein the extraction tower is connected to a three-stage evaporation device, which is a device composed by connecting three groups of evaporators with a vaporizer in series, in a positive manner, the top of the extraction tower is connected to the three-stage evaporation device and the bottom is connected to a gas-liquid separator through a hot water heat exchanger, and the liquid phase of the gas-liquid separator is the outlet of the caprolactam. 10. A product prepared by means of the nylon 6 manufacturing process according to any one of claims 1 to 7, or the nylon 6 manufacturing system according to claims 8 or 9.