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Bis(2-Hydroxyethyl) Terephthalate와 1,4-Butanediol의 에스테르 교환 반응
전형철,한명완,Jeon, Hyeongcheol,Han, Myungwan 한국화학공학회 2018 Korean Chemical Engineering Research(HWAHAK KONGHA Vol.56 No.1
Transesterification of BHET (Bis (2-Hydroxyethyl) Terephthalate), monomer of PET (Poly Ethylene Terephthalate) to BHBT (Bis (4-Hydroxybutyl Terephthate), monomer of PBT (Poly Butylene Terephthalate), using 1,4-BD (1,4-butanediol) were investigated. Zinc acetate was used as a catalyst for the reaction. Amounts of BHET, EG, and THF (Tetrahydrofuran) in a batch reactor were measured for determining the reaction kinetics. Mathematical models of the batch reactor for the transesterification reaction were developed and used to characterize the reaction kinetics and the composition distribution of the reaction products. Model predictions for the transesterification were in good agreement with experimental results. 본 연구에서는 PET (Poly Ethylene Terephthalate)의 단량체인 BHET (bis (2-Hydroxyethyl) Terephthalate)와 1,4-BD(1,4-Butanediol)의에스테르교환반응을활용하여 PBT (Poly Butylene Terephthalate)의단량체인 BHBT (Bis (4-Hydroxybutyl Terephthate)를 생성하는 반응에 대하여 조사하였다. 이 반응의 촉매로 Zinc Acetate를 사용하였다. 회분식 반응기를 통하여 BHET, EG (Ethylene Glycol), THF (Tetrahydrofuran)의 양을 정량하여 반응 kinetics 모델을 구성하였다. 제시된 모델을 통하여 반응속도와 반응물의 조성 분포를 조사하였고, 이 모델의 예측 값과 실험 값들이 잘 일치함을 보였다.
물/유기용매 분리를 위한 증류-투과증발막 혼성공정의 최적화
양정인,한명완,Yang, Jeongin,Han, Myungwan 한국화학공학회 2018 Korean Chemical Engineering Research(HWAHAK KONGHA Vol.56 No.1
Separating a mixture having an azeotrope or low relative volatility with single distillation column is difficult. Separating water-acetic acid mixture and water-ethanol mixture with a distillation column consumes a lot of energy. Pervaporation membrane can be used to separate the mixture in the concentration region where separation is difficult with distillation. We simulated a distillation-membrane hybrid process where membrane is located on the head of the distillation column for efficient separation of water-acetic acid and water-ethanol mixture. Permeability data were obtained from experiments and literature. We formulated an optimization problem for the process with total annual cost (TAC) as an objective function and major design variables as optimization variables. Major optimization variable affecting TAC of the hybrid process was shown to be distillate concentration. We also suggested a simplified optimization procedure to get a close-to-optimal solution. 공비점이 존재하거나 상대휘발도 차이가 적은 2성분 혼합물은 단일 증류탑으로 분리하기 어렵다. 이때 혼합물에서 분리가 어려운 영역을 투과증발막을 사용하여 분리하면 효율적인 공정을 설계할 수 있다. 본 연구에서는 물-유기용매 혼합물을 분리하기 위한 증류-투과증발막 혼성공정을 제시하고, 물-초산 혼합물과 물-에탄올 혼합물의 분리공정을 각각 모사하였다. 증류탑 상부 흐름이 친수성 막을 통과하여 물을 높은 순도로 분리하는 공정을 모사하였다. 실험과 문헌에서 얻은 친수성 막의 투과도를 토대로 막 모델을 만들어 막 면적을 계산하였다. 제시한 공정의 최적화를 위해, 목적함수를 연간 총 비용으로 정하고 주요 설계 변수들을 최적화 변수로 하여 최적화 문제를 구성하였다. 또한, 혼성공정의 각 최적화 변수의 변화에 따른 목적함수 값의 변화 추세를 나타내고 최적화 변수를 최적점에 가까운 값으로 쉽게 추측할 수 있는 방법을 제안하였다.
코크 생성 억제를 위한 이산화탄소 건식 개질 반응기의 최적 설계
이종원 ( Jongwon Lee ),한명완 ( Myungwan Han ),김범식 ( Beomsik Kim ) 한국화학공학회 2018 Korean Chemical Engineering Research(HWAHAK KONGHA Vol.56 No.2
As global warming accelerates, greenhouse gas reduction becomes more important. Carbon dioxide dry reforming is a promising green-house gas reduction technology that can obtain CO and H<sub>2</sub> which are high value-added materials by utilizing CO<sub>2</sub> and CH<sub>4</sub> which are greenhouse gases. However, there is a significant coking problem during operation of the dry reforming reactor. Because the carbon dioxide dry reforming is a strong endothermic reaction, the temperature of the reactor drops near the reactor inlet and causes coke formation. To solve this problem, it is important to ensure that the reaction takes place in a temperature range where coke production is minimized. In this study, we proposed a design method that can maintain reaction temperature in the region where the coke is rarely generated by using the new catalyst configuration method. The design method also optimizes the reactor by solving the optimization problem which minimizes the reactor length for a given reaction conversion by using the fuel flow rate, catalyst density, and output temperature by section as optimization variables.
부틸 아세테이트 합성을 위한 공비첨가제 사용 반회분식 반응증류
양정인 ( Jeongin Yang ),전형철 ( Hyeongcheol Jeon ),한명완 ( Myungwan Han ) 한국화학공학회 2017 Korean Chemical Engineering Research(HWAHAK KONGHA Vol.55 No.3
Butyl acetate is produced from acetic acid and butanol via an esterification reaction in a reactive distillation column. Entrainer can be used for efficient removal of produced water from the reaction region, leading to significant improvement of the column performance. Batch reactive distillation has clear advantages over continuous one in terms of flexibility and adaptability in a small plant. We studied batch and semi-batch reactive distillation processes through process simulation and pilot-scale experiments. We investigated process configuration and type of entrainer for improvement of the column performance and suggested a novel cyclic operation strategy using the semi-batch reactive distillation column. The cyclic strategy was shown to give relatively high production rate and stable operation.
부틸 아세테이트 생산을 위한 외부 공비제 첨가 반응증류: 파일럿 규모 실험을 통한 연구
양정인 ( Jeongin Yang ),임홍규 ( Honggyu Lim ),임성규 ( Sungkyu Lim ),백가영 ( Gayoung Baek ),한명완 ( Myungwan Han ) 한국화학공학회 2016 Korean Chemical Engineering Research(HWAHAK KONGHA Vol.54 No.5
Butyl acetate is produced from acetic acid and butanol via an esterification reaction in reactive distillation (RD). The product, butyl acetate, has been used as an internal entrainer until now. In this case, butyl acetate and water are removed at the top of column and separated into two different phases (organic and aqueous phases) after condensation, and butyl acetate rich organic phase is refluxed into the RD. This method makes butyl acetate remain high at the reactive zone, leading to lower equilibrium conversion and product yield. We introduced an extraneous entrainer to solve the problem. The extraneous entrainer forms a new azeotrope with water. The proposed process provides lower concentration of butyl acetate in the reactive zone than conventional RD processes using an internal entrainer. We compared the yield and production rate of butyl acetate between the proposed and conventional processes through pilot-scale experiments. Experimental and simulation results showed that the proposed process was more efficient than conventional process using internal entrainer.