Comparison of Energy Consumption and CO2 Emission for Three Steel Production Routes—Integrated Steel Plant Equipped with Blast Furnace, Oxygen Blast Furnace or COREX
Abstract
:1. Introduction
2. Models and Methods
2.1. Static Process Models
2.1.1. The TGR-OBF Process Model
2.1.2. The COREX Process Model
2.2. Integrated Steel Plant
- In the calculation of the TGR-OBF and COREX process models, the temperature and composition of hot metal, the chemical composition of raw materials were considered to be the same as that of the BF process in the Jingtang steel plant, and it was feasible for the two ironmaking processes. For the TGR-OBF process, the raw materials with the same composition as the BF were flux, coke, coal, sinter, and pellets. For the COREX process, the raw materials with the same composition as the BF were flux and coal.
- For a better comparison of the three ironmaking technology in the ISP, the static process model of the TGR-OBF established in this paper was based on the current feasible technology, and the CCS technology was not considered in this study.
- In the analysis of an ISP with the TGR-OBF and an ISP with the COREX, the operation data for the raw materials handling process, steelmaking process, rolling process, lime making process, oxygen plant, and power plant were all from the Jingtang steel plant. The input and output values of the raw materials handling process were proportional to the raw material consumption of the TGR-OBF process and COREX process, respectively.
- In an ISP, the metallurgical gas was preferentially supplied to the steel manufacturing system for use. The surplus gas was transported to the power plant, and the generating efficiency was 33%.
- The blast furnace blower was driven by electricity and the power consumption was 0.103 kWh/m3.
- Since the calculation of TRT power generation is very complex. In this study, the generating capacity was simplified to be only related to the flow of top gas, it was 0.028 kWh/m3.
- The electricity consumption of cryogenic oxygen process is 0.86 kWh/m3-oxygen.
2.3. Methods to Calculate Comprehensive Energy Consumption
2.4. Methods to Calculate CO2 Emissions
3. Results and Discussion
3.1. Material Flows Analysis
3.2. Metallurgical Gas Analysis
3.3. Electricity Analysis
3.4. Comprehensive Energy Consumption Analysis
3.5. CO2 Emissions Analysis
4. Conclusions
Supplementary Materials
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Nomenclature
m | mass of substance (kg) |
eiin, eiout | the input and output energy substances (kg/t crude steel) |
CE, CEd, CEi, CEc | the net, direct, indirect, and credit of the CO2 emissions (t/t crude steel) |
Cin, Cp, Cbyp | the amount of total carbon input to the system, the amount of carbon fixed in the product, the amount of carbon fixed in the byproduct (t/t crude steel) |
h | Specific enthalpy of chemical reaction (kJ/kg) |
H | enthalpy value (kJ) |
K | equilibrium constant |
OD | oxidation degree |
pi | energy conversion coefficient for substance i (GJ/kg) |
q | sensible heat (kJ/kg) |
R | basicity |
T | temperature (K) |
v | gas volume fraction |
V | gas volume (m3) |
ω | mass fraction |
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Song, J.; Jiang, Z.; Bao, C.; Xu, A. Comparison of Energy Consumption and CO2 Emission for Three Steel Production Routes—Integrated Steel Plant Equipped with Blast Furnace, Oxygen Blast Furnace or COREX. Metals 2019, 9, 364. https://doi.org/10.3390/met9030364
Song J, Jiang Z, Bao C, Xu A. Comparison of Energy Consumption and CO2 Emission for Three Steel Production Routes—Integrated Steel Plant Equipped with Blast Furnace, Oxygen Blast Furnace or COREX. Metals. 2019; 9(3):364. https://doi.org/10.3390/met9030364
Chicago/Turabian StyleSong, Jiayuan, Zeyi Jiang, Cheng Bao, and Anjun Xu. 2019. "Comparison of Energy Consumption and CO2 Emission for Three Steel Production Routes—Integrated Steel Plant Equipped with Blast Furnace, Oxygen Blast Furnace or COREX" Metals 9, no. 3: 364. https://doi.org/10.3390/met9030364
APA StyleSong, J., Jiang, Z., Bao, C., & Xu, A. (2019). Comparison of Energy Consumption and CO2 Emission for Three Steel Production Routes—Integrated Steel Plant Equipped with Blast Furnace, Oxygen Blast Furnace or COREX. Metals, 9(3), 364. https://doi.org/10.3390/met9030364