TY  - JOUR
AU  - Yuan, Maobo
AU  - Liu, Hu
AU  - Wu, Ying
AU  - Liang, Yong
AU  - Deng, Lei
AU  - Belošević, Srđan
AU  - Tomanović, Ivan D.
AU  - Che, Defu
PY  - 2022
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/10190
AB  - Fireside metal temperature is quite important in the safety evaluation of boiler water-cooled wall. While little literature reported the accurate temperature calculation model for spiral water-cooled wall. This paper proposes a coordinate transformation method for heat reallocation in the spiral water-cooled wall temperature calculation. A computational fluid dynamics (CFD) model based on a 600 MW tangentially coal-fired boiler is used to provide the original heat flux distributions under various boiler loads. The reallocated heat distribution directly maps with the flow path of the spiral water-cooled wall. The combination of the heat reallocation model and thermal-hydraulic model is realized in MATLAB platform. The calculated temperature distributions at the outlet of the spiral water-cooled wall agree well with the in-situ data, and the maximum relative errors under 100% BMCR load and 75% THA load are 2.7% and 3.2%, respectively. The numerical results show that the working fluid flow rates of the divided loops are almost equal and the maximum metal temperatures of the spiral water-cooled wall are 732.1 K, 710.4 K, 760.9 K and 792.9 K under 100% BMCR, 75% THA, 50% THA and 35% BMCR loads, respectively. The local overheating is likely to occur in low boiler load. This model is intended to improve the metal temperature calculation method of the spiral water-cooled wall, which could benefit the safety monitoring of the boiler under variable loads. © 2022 Elsevier Masson SAS
T2  - International Journal of Thermal Sciences
T1  - Coordinate transformation method for heat reallocation in the spiral water-cooled wall temperature calculation
VL  - 177
SP  - 107557
DO  - 10.1016/j.ijthermalsci.2022.107557
ER  - 

@article{
author = "Yuan, Maobo and Liu, Hu and Wu, Ying and Liang, Yong and Deng, Lei and Belošević, Srđan and Tomanović, Ivan D. and Che, Defu",
year = "2022",
abstract = "Fireside metal temperature is quite important in the safety evaluation of boiler water-cooled wall. While little literature reported the accurate temperature calculation model for spiral water-cooled wall. This paper proposes a coordinate transformation method for heat reallocation in the spiral water-cooled wall temperature calculation. A computational fluid dynamics (CFD) model based on a 600 MW tangentially coal-fired boiler is used to provide the original heat flux distributions under various boiler loads. The reallocated heat distribution directly maps with the flow path of the spiral water-cooled wall. The combination of the heat reallocation model and thermal-hydraulic model is realized in MATLAB platform. The calculated temperature distributions at the outlet of the spiral water-cooled wall agree well with the in-situ data, and the maximum relative errors under 100% BMCR load and 75% THA load are 2.7% and 3.2%, respectively. The numerical results show that the working fluid flow rates of the divided loops are almost equal and the maximum metal temperatures of the spiral water-cooled wall are 732.1 K, 710.4 K, 760.9 K and 792.9 K under 100% BMCR, 75% THA, 50% THA and 35% BMCR loads, respectively. The local overheating is likely to occur in low boiler load. This model is intended to improve the metal temperature calculation method of the spiral water-cooled wall, which could benefit the safety monitoring of the boiler under variable loads. © 2022 Elsevier Masson SAS",
journal = "International Journal of Thermal Sciences",
title = "Coordinate transformation method for heat reallocation in the spiral water-cooled wall temperature calculation",
volume = "177",
pages = "107557",
doi = "10.1016/j.ijthermalsci.2022.107557"
}

Yuan, M., Liu, H., Wu, Y., Liang, Y., Deng, L., Belošević, S., Tomanović, I. D.,& Che, D.. (2022). Coordinate transformation method for heat reallocation in the spiral water-cooled wall temperature calculation. in International Journal of Thermal Sciences, 177, 107557.
https://doi.org/10.1016/j.ijthermalsci.2022.107557

Yuan M, Liu H, Wu Y, Liang Y, Deng L, Belošević S, Tomanović ID, Che D. Coordinate transformation method for heat reallocation in the spiral water-cooled wall temperature calculation. in International Journal of Thermal Sciences. 2022;177:107557.
doi:10.1016/j.ijthermalsci.2022.107557 .

Yuan, Maobo, Liu, Hu, Wu, Ying, Liang, Yong, Deng, Lei, Belošević, Srđan, Tomanović, Ivan D., Che, Defu, "Coordinate transformation method for heat reallocation in the spiral water-cooled wall temperature calculation" in International Journal of Thermal Sciences, 177 (2022):107557,
https://doi.org/10.1016/j.ijthermalsci.2022.107557 . .

TY  - JOUR
AU  - Deng, Lei
AU  - Dong, Lingxiao
AU  - Bai, Yang
AU  - Wu, Yuhao
AU  - Liu, Hu
AU  - Belošević, Srđan
AU  - Tomanović, Ivan
AU  - Che, Defu
PY  - 2022
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/10227
AB  - The ultra-supercritical double-reheat boiler has attracted more attention because of high parameters (steam with high temperature and pressure), low pollution and large capacity. However, there are some difficulties in the development of this technology, such as adjusting the reheat steam temperature. In this study, computational fluid dynamics simulation is used to analyze a 660 MW double-reheat tower-type pulverized coal-fired boiler. The influence of flue gas recirculation (FGR) on heat transfer characteristics and combustion process in the furnace (including heating surfaces in the upper parts of the furnace) are evaluated. The user-defined function approach predicates the CO reduction effect on NOx. The results show that the flow at the horizontal section through the centerline of recirculating flus gas nozzles is rotating. The velocity distribution changes into an elliptical rotating flow when FGR ratio is 20%. At higher FGR ratios, the high-temperature area (1565–1700 K) shrinks and both the NOx concentration at the low-temperature superheater outlet and the O2 concentration in the burner zone descend. The O2 concentration at the low-temperature superheater outlet first increases and then decreases. In the main combustion zone, the heat flux peak of water-cooled wall is about 330 kW m−2. As FGR ratio increases from 0% to 20%, the rate of heat absorption of water-cooled wall to that of total boiler decreases by 3.50%. These rates for reheater and superheater increase by 2.53% and 2.13%, respectively.
T2  - Fuel
T1  - Effects of flue gas recirculation on combustion and heat flux distribution in 660 MW double-reheat tower-type boiler
VL  - 321
SP  - 123988
DO  - 10.1016/j.fuel.2022.123988
ER  - 

@article{
author = "Deng, Lei and Dong, Lingxiao and Bai, Yang and Wu, Yuhao and Liu, Hu and Belošević, Srđan and Tomanović, Ivan and Che, Defu",
year = "2022",
abstract = "The ultra-supercritical double-reheat boiler has attracted more attention because of high parameters (steam with high temperature and pressure), low pollution and large capacity. However, there are some difficulties in the development of this technology, such as adjusting the reheat steam temperature. In this study, computational fluid dynamics simulation is used to analyze a 660 MW double-reheat tower-type pulverized coal-fired boiler. The influence of flue gas recirculation (FGR) on heat transfer characteristics and combustion process in the furnace (including heating surfaces in the upper parts of the furnace) are evaluated. The user-defined function approach predicates the CO reduction effect on NOx. The results show that the flow at the horizontal section through the centerline of recirculating flus gas nozzles is rotating. The velocity distribution changes into an elliptical rotating flow when FGR ratio is 20%. At higher FGR ratios, the high-temperature area (1565–1700 K) shrinks and both the NOx concentration at the low-temperature superheater outlet and the O2 concentration in the burner zone descend. The O2 concentration at the low-temperature superheater outlet first increases and then decreases. In the main combustion zone, the heat flux peak of water-cooled wall is about 330 kW m−2. As FGR ratio increases from 0% to 20%, the rate of heat absorption of water-cooled wall to that of total boiler decreases by 3.50%. These rates for reheater and superheater increase by 2.53% and 2.13%, respectively.",
journal = "Fuel",
title = "Effects of flue gas recirculation on combustion and heat flux distribution in 660 MW double-reheat tower-type boiler",
volume = "321",
pages = "123988",
doi = "10.1016/j.fuel.2022.123988"
}

Deng, L., Dong, L., Bai, Y., Wu, Y., Liu, H., Belošević, S., Tomanović, I.,& Che, D.. (2022). Effects of flue gas recirculation on combustion and heat flux distribution in 660 MW double-reheat tower-type boiler. in Fuel, 321, 123988.
https://doi.org/10.1016/j.fuel.2022.123988

Deng L, Dong L, Bai Y, Wu Y, Liu H, Belošević S, Tomanović I, Che D. Effects of flue gas recirculation on combustion and heat flux distribution in 660 MW double-reheat tower-type boiler. in Fuel. 2022;321:123988.
doi:10.1016/j.fuel.2022.123988 .

Deng, Lei, Dong, Lingxiao, Bai, Yang, Wu, Yuhao, Liu, Hu, Belošević, Srđan, Tomanović, Ivan, Che, Defu, "Effects of flue gas recirculation on combustion and heat flux distribution in 660 MW double-reheat tower-type boiler" in Fuel, 321 (2022):123988,
https://doi.org/10.1016/j.fuel.2022.123988 . .

TY  - JOUR
AU  - Deng, Lei
AU  - Zhang, Yan
AU  - Ma, Shihao
AU  - Zhu, Zhengrong
AU  - Liu, Hu
AU  - Belošević, Srđan
AU  - Tomanović, Ivan
AU  - Che, Defu
PY  - 2021
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/13110
AB  - Ultra‐supercritical double‐reheat technology, as one of the most advanced coal‐fired power generation technology, is an important direction for emission reduction and energy saving in the world. In this study, the numerical calculation was executed in a 660‐MW ultra‐supercritical double‐reheat tower‐type boiler under deep‐air‐staging conditions. The refined HCN oxidation model was adopted to substitute the default model implemented by the user‐defined functions to calculate the NO x emission. The influences of the boiler load, over‐fire air (OFA) ratio, and excess air coefficient on temperature, species, and heat flux distributions were investigated. Results show that the decrement of the boiler load from boiler maximum continuous rating to 50% turbine heat acceptance gives rise to an increase of NO x emission. The heat flux distributions along with the furnace width direction present bell shaped. When the OFA ratio rises from 17% to 43%, NO x emission descends from 357.7 to 179.3 mg m −3 at the furnace outlet, and the heat flux distributions become more uniform along with the furnace width direction with lower peaks. Temperatures, species, and heat flux distributions are similar under the three different excess air coefficients. The NO x emission is the lowest when the excess air coefficient is 1.15. The results could provide a reference for combustion characteristics optimization and hydrodynamic calculation of ultra‐supercritical double‐reheat tower‐type boiler.
T2  - Asia-Pacific Journal of Chemical Engineering
T1  - Numerical study on combustion characteristics and heat flux distributions of 660‐MW ultra‐supercritical double‐reheat tower‐type boiler
VL  - 16
IS  - 3
SP  - e2631
DO  - 10.1002/apj.2631
ER  - 

@article{
author = "Deng, Lei and Zhang, Yan and Ma, Shihao and Zhu, Zhengrong and Liu, Hu and Belošević, Srđan and Tomanović, Ivan and Che, Defu",
year = "2021",
abstract = "Ultra‐supercritical double‐reheat technology, as one of the most advanced coal‐fired power generation technology, is an important direction for emission reduction and energy saving in the world. In this study, the numerical calculation was executed in a 660‐MW ultra‐supercritical double‐reheat tower‐type boiler under deep‐air‐staging conditions. The refined HCN oxidation model was adopted to substitute the default model implemented by the user‐defined functions to calculate the NO x emission. The influences of the boiler load, over‐fire air (OFA) ratio, and excess air coefficient on temperature, species, and heat flux distributions were investigated. Results show that the decrement of the boiler load from boiler maximum continuous rating to 50% turbine heat acceptance gives rise to an increase of NO x emission. The heat flux distributions along with the furnace width direction present bell shaped. When the OFA ratio rises from 17% to 43%, NO x emission descends from 357.7 to 179.3 mg m −3 at the furnace outlet, and the heat flux distributions become more uniform along with the furnace width direction with lower peaks. Temperatures, species, and heat flux distributions are similar under the three different excess air coefficients. The NO x emission is the lowest when the excess air coefficient is 1.15. The results could provide a reference for combustion characteristics optimization and hydrodynamic calculation of ultra‐supercritical double‐reheat tower‐type boiler.",
journal = "Asia-Pacific Journal of Chemical Engineering",
title = "Numerical study on combustion characteristics and heat flux distributions of 660‐MW ultra‐supercritical double‐reheat tower‐type boiler",
volume = "16",
number = "3",
pages = "e2631",
doi = "10.1002/apj.2631"
}

Deng, L., Zhang, Y., Ma, S., Zhu, Z., Liu, H., Belošević, S., Tomanović, I.,& Che, D.. (2021). Numerical study on combustion characteristics and heat flux distributions of 660‐MW ultra‐supercritical double‐reheat tower‐type boiler. in Asia-Pacific Journal of Chemical Engineering, 16(3), e2631.
https://doi.org/10.1002/apj.2631

Deng L, Zhang Y, Ma S, Zhu Z, Liu H, Belošević S, Tomanović I, Che D. Numerical study on combustion characteristics and heat flux distributions of 660‐MW ultra‐supercritical double‐reheat tower‐type boiler. in Asia-Pacific Journal of Chemical Engineering. 2021;16(3):e2631.
doi:10.1002/apj.2631 .

Deng, Lei, Zhang, Yan, Ma, Shihao, Zhu, Zhengrong, Liu, Hu, Belošević, Srđan, Tomanović, Ivan, Che, Defu, "Numerical study on combustion characteristics and heat flux distributions of 660‐MW ultra‐supercritical double‐reheat tower‐type boiler" in Asia-Pacific Journal of Chemical Engineering, 16, no. 3 (2021):e2631,
https://doi.org/10.1002/apj.2631 . .