| 1 |
Optimal operating strategy of ash deposit removal system to maximize boiler efficiency using CFD and a thermal transfer efficiency model
Park HD, Lee JS, Lim JH, Cho HT, Kim JH
Journal of Industrial and Engineering Chemistry, 110, 301, 2022 |
| 2 |
CFD를 활용한 크래프트 회수보일러 내부 노즈 아치 구조에 따른 열교환 효율 분석
장용호, 박현도, 임경필, 박한신, 김정환, 조형태
Applied Chemistry for Engineering, 32(2), 149, 2021 |
| 3 |
A sampling-based stochastic optimization for a boiler process in a pulp industry
de Almeida GM, Park SW, Kim SC, Lee CJ
Korean Journal of Chemical Engineering, 37(4), 588, 2020 |
| 4 |
Optimizing the heat transfer performance of the recovery boiler superheaters using simulated annealing, surrogate modeling, and Cheek computational fluid dynamics
Maakala V, Jarvinen M, Vuorinen V
Energy, 160, 361, 2018 |
| 5 |
An inhouse code for simulating heat recovery from boilers to heat water
Ramadan M, Khaled M, Haddad A, Abdulhay B, Durrant A, El Hage H
Energy, 157, 200, 2018 |
| 6 |
Unsteady CFD analysis of kraft recovery boiler fly-ash trajectories, sticking efficiencies and deposition rates with a mechanistic particle rebound-stick model
Perez MG, Vakkilainen E, Hyppanen T
Fuel, 181, 408, 2016 |
| 7 |
2D dynamic mesh model for deposit shape prediction in boiler banks of recovery boilers with different tube spacing arrangements
Perez MG, Vakkilainen E, Hyppanen T
Fuel, 158, 139, 2015 |
| 8 |
Numerical modeling of fine particle and deposit formation in a recovery boiler
Leppanen A, Tran H, Taipale R, Valimaki E, Oksanen A
Fuel, 129, 45, 2014 |
| 9 |
Modeling and multi-objective exergy based optimization of a combined cycle power plant using a genetic algorithm
Kaviri AG, Jaafar MNM, Lazim TM
Energy Conversion and Management, 58, 94, 2012 |
| 10 |
An Atomization Model for Splash Plate Nozzles
Sarchami A, Ashgriz N, Tran H
AIChE Journal, 56(4), 849, 2010 |
