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Influence of unburned pulverized coal on gasification reaction of coke in blast furnace

  • Yi-fan Chai EMAIL logo , Guo-ping Luo EMAIL logo , Sheng-li An , Jun Peng and Yi-ci Wang
Published/Copyright: July 20, 2019
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High Temperature Materials and Processes
From the journal High Temperature Materials and Processes Volume 38 Issue 2019

Abstract

In order to explore the influence of unburned pulverized coal on gasification reaction of coke in blast furnace, kinetic rules of gasification reaction between CO2 and coke powder adding pulverized coals with different volatiles were studied by thermogravimetric analysis. The results showed that weight-loss ratio of samples reacted with CO2 increased after adding pulverized coal, and the weight-loss ratio rose with the increase of coal’s addition. When the content of pulverized coal was up to 50%, the weight-loss ratio of the sample which adding pulverized coal with high volatile was higher under the same temperature. The activation energy about C-CO2 gasification reaction of samples reduced observably after adding pulverized coal. The activation energy of samples had a largest decrease with 83.408 kJ mol−1 at the range of 1223 K~1373 K and it was 28.97 kJ mol−1 at the range of 1373 K~1523 K. The addition of pulverized coal with high volatile can reduce the reaction activation energy of samples more effectively. In the soft melting zone, the gasification reaction model of coke blocks attached the unburned pulverized coal was up to unreacted core model and porous volume-reacted model jointly.

Keywords: unburnt pulverized coal; coke; carbon solution loss reaction; reactivity; kinetics
PACS: 82.20.-w; 89.20.Kk

1 Introduction

Pulverized coal injection in blast furnace is the effective way to reduce coke consumption and fuel ratio,while a certain extent, reduce the environmental pollution caused by coking. Currently, due to the cost efficiency of every steel companies is the impending event, pulverized coal injection ratio is improving. Under the conditions of the large coal injection ratio, pulverized coal is injected at a high speed through the tuyere, and the time of coal pyrolysis and char combustion is very short (about 20ms) in raceway. Therefore the residual coke is not fired, and the unburned char will react with other substances further in the blast furnace [1, 2, 3]. Figure 1 is a schematic about consumption way of pulverized coal when it was injected into the blast furnace. Some papers pointed out that [4, 5] the reaction

Figure 1 Consumption of pulverized coal in blast furnace
Figure 1

Consumption of pulverized coal in blast furnace

between unburned pulverized coal and CO2 is happened in the vicinity of coke layer in the cohesive zone.

Coke in the blast furnace is act as a heat source, reducing agent, carburizing agent involved in physical and chemical reactions in furnace. More importantly, it also plays the role of the skeleton supporting the burden. The smelting process was strengthened by pulverized coal injection representatively, and the residence time of coke in blast furnace especially in deadman is prolonged. Under these conditions, coke experienced greater damaging effects, the coke layer became thinner, and "coke window" layer of cohesive zone which is maintained permeability became smaller. So the skeleton effect of coke is particularly important [6, 7, 8, 9, 10].

The role of coke in the blast furnace skeleton is good or bad, depends both on the quality of coke and smelting process of blast furnace. Numerous studies showed that the pulverization of coke in the furnace is the root cause of permeability deterioration. The pulverization of coke in the blast furnace is mainly due to the occurrence of solution loss reaction with CO 2.With the increase of the amount of pulverized coal injection, the number of unburned pulverized coal in raceway was increasing, and therefore the impact of unburned pulverized coal to gasification reaction of coke cannot be ignored [11]. This article studied the reaction behavior of coexistence of unburned pulverized coal and coke with CO2 by thermal gravimetric analysis.

2 Experimental

The coke and coal of a 3200m3 blast furnace were selected for the experiment. The coke reactivity index (CRI) is 27.7% and coke strength after reduction (CSR) is 63.83%. In order to compare the influence of unburned pulverized coal to gasification reaction of coke after pulverized coal with different volatile matter injected, two kinds of pulverized coals were selected. Their proximate analysis and ultimate analysis are shown in Table 1.

Table 1

Ultimate analysis and ultimate analysis of anthracite

Proximate analysis, ad/%(mass)Ultimate analysis, ad/%(mass)
VolatileAshFixed CarbonCHNOS
1#Coal9.317.5483.1585.423.060.801.820.24
2#Coal13.639.6576.7279.323.700.705.800.62

The coke and coal mentioned above were made into powder, their particle sizes were controled at 0.074mm or less. Before the test, pulverized coal and coke should be mixed uniformly according to a certain proportion: coal’s quality accounted for 10%, 30%, 50% the mixed sample’s quality and the specific mixing scheme is shown in Table 2.

Table 2

Proportion scheme of experimental sample

No.ProportionNo.Proportion
1Coke: 1#Coal=9: 14Coke: 2#Coal=9: 1
2Coke: 1#Coal=7: 35Coke: 2#Coal=7: 3
3Coke: 1#Coal=1: 16Coke: 2#Coal=1: 1

Experiments conducted through the thermo gravimetric analyzer (TGA) of NETZSCH. The system collected samples automatically, and the weight-loss curves were plotted by the computer. 18mg of every experimental sample was weighed and placed on the heat balance. Then the temperature of samples were raised from indoor temperature to 973 K in argon gas atmosphere at the heating rate of 293 K/min to remove volatile. The unburned pulverized coal appeared in this process. When the temperature reached 973K, CO2 gas was needed for further heating up from 973 K to 1523 K at the heating rate of 288 K/min to make carbon solution loss reaction conduct adequately. At the same time, the coke powder without pulverized coal was experimented repeatedly to compare the impact of unburned pulverized coal to solution loss reaction of coke.

3 Results and discussion

3.1 Weight-loss rate of the sample reacts with CO2

Hu’s study has shown that [12], the solution loss reaction of coke began to occur at 1073 K and carbon solution loss reaction was taken place in a certain temperature range. Due to the various volatile of different test samples, the initial quality of test samples was different when they react with CO2 at 973 K. So the different effects of addition of pulverized coal to coke can be compared by weight-loss rate. The curves of weight-loss rate at different temperature obtained from thermogravimetric experiment are shown in Figure 2.

Figure 2 Weight-loss rate curves of gasification reaction on char-CO2
Figure 2

Weight-loss rate curves of gasification reaction on char-CO2

Weight-loss rate curves were based on the actual quality of the samples at 1023 K. As the temperature rose, the samples gradually reacted with CO2, and the weight-loss value increased. As can be seen from Figure 2, after the pulverized coal adding into coke powder, the weight-loss rate increased at the same temperature. And with the increase of the content of pulverized coal, this trend became even more obvious. Meanwhile, the effects of pulverized coals with different volatile to reaction weight-loss rate of samples were different. When the content of pulverized coal was 10% or 30%, the effect on weight-loss rate of the sample was little. But when the content was 50%, the weight-loss rate of the sample containing high volatile pulverized coal was greater at the same temperature.

In order to explore the reasons for the increase of weight-loss rate after adding pulverized coal, the two pulverized coals were used to do the same gasification reaction experiment solely. According to the TGA experimental data, the weight-loss rates of the two pulverized coals reacted with CO2 at different temperatures were obtained. Table 3 lists the weight-loss rates of 100% pulverized coal and 100% coke powder from 1173 K to 1473 K.

Table 3

Weight-loss rate of pulverized coal and coke separately at different temperatures

Temperature (K)1173122312731323137314231473
Weight-loss1#Coal1.6604.2808.38016.45431.61648.49866.561
Rate2#Coal3.1976.57811.30419.9834.40550.87668.197
%Coke0.0371.3154.07810.51520.67831.59244.853

Due to the huge difference in the reactivity, it can be considered that the unburned pulverized coal and the coke powder reacted with CO2 relatively and independently in mixed samples. From Table 3, it is clearly observed that the weight-loss rate of the pulverized coal reacted with CO2 is far greater than the coke at the same temperature. And the weight-loss rate of the pulverized coal with high volatile is greater than the low volatile pulverized coal. Therefore, the weight loss of mixed sample with coal and coke is caused by the gasification reaction between unburned pulverized coal and CO2. This shows that the unburned pulverized coal is a protective effect on gasification reaction of coke. Because of the detrainment of volatile can make the porosity of pulverized coal be larger, so the specific surface area of the unburned pulverized coal made from the coal with the higher volatile is large. The reactivity of this unburned pulverized coal reacting with CO2 is high. It can be concluded that when injected the high volatile pulverized coal into blast furnace, the reaction of unburned pulverized coal with CO2 is taken part in the upper of cohesive zone sufficiently, and it can play a better protective effect to the degradation of coke.

3.2 Kinetics analysis of gasification reaction

According to the experimental weight-loss curves, the rate of weight-loss change (α) can be determined when the reaction has proceeded to a certain time (t):

(1)α=ω0ωtω0ω

As the gas flow of CO2 was constant in the experiment, and the reaction was under atmospheric pressure, so the PCO2 is a constant. According to the rate equation of gasification reaction of char-CO2 (2) and the Arrhenius Equation (3), the general form of kinetic Equation (4) can be obtained.

(2)dαdt=k(1α)n
(3)k=AeERT
(4)dαdT=AβeERT(1α)n=AβeERTf(α)

The kinetic parameters calculated from the above equations are the apparent kinetic parameters of experience.

There are many computing method of kinetic parameters deduced from the general form of kinetic equations [13, 14, 15, 16]. This article used the integral method of Coats-Redfern, using the non-isothermal method of a single procedure of temperature control. That is to say the heating rate (β) is a constant. After solving the integral on both sides of the Equation (4) and set the initial state of the equation (α = 0, T = T0), the Equation (5) was obtained as follow.

(5)0αdαf(α)=AβT0TeERTdT

The reaction rate at the low temperature is negligible usually. So that the Equation (5) becomes:

(6)0αdαf(α)=Aβ0TeERTdT

Make the definition: g(α)=0αdαf(α),and the gasification reaction of C-CO2 can be described as a first-order reaction [17, 18]. So the reaction order n=1, and f (α) = 1 − α, the Equation (6) becomes:

(7)g(α)=ART2βE12RTEeERT

After solving the natural logarithm on both sides of the Equation (7):

(8)lng(α)T2=lnARβE12RTEERT

During the experiments, the heating rate was determined (β = 288 K/min). Therefore, the reaction temperature, and most typically in terms of E, the value of lnARβE12RTEis a constant. Set up X=1T,Y=lng(α)T2the approximate line can be obtained by plotting to X-Y, and the activation energy(E) and the pre-exponential factor (A) can be calculated by Equation (7). Results of kinetics calculation are shown in Table 4.

Table 4

Kinetics calculation of carbon dissolving reaction

ProportionTemperature interval (K)Fitting curve (Y=aX+b)Similarity (R2)Activation energy(E)/kJ·mol−1
Coke1223~1373Y=246644X+5.79770.9972246.644
1373~1523Y=137272X-3.89480.9993137.272
Coke+10%1#coal1223~1373Y=236362X+6.78210.9972236.362
1373~1523Y=115060X-5.65220.9957115.060
Coke+30%1#coal1223~1373Y=221245X+4.00990.9985221.245
1373~1523Y=110222X-5.80470.9904110.222
Coke+50%1#coal1223~1373Y=202208X+2.18320.9998202.208
1373~1523Y=108302X-5.8690.9861108.302
Coke+10%2#coal1223~1373Y=196140X+1.45930.9989196.140
1373~1523Y=114838X-5.66740.9992114.838
Coke+30%2#coal1223~1373Y=187723X+0.85080.9975187.723
1373~1523Y=116178X-5.33950.9930116.178
Coke+50%2#coal1223~1373Y=163236X-1.05010.9956163.236
1373~1523Y=119195X-4.82580.9927119.195

To study the relationship between the content of pulverized coal in the samples and changes of activation energy, the data of Table 4 were plotted. Figure 3 shows that in the two temperature ranges of 1223 K~1373 K and 1373 K~1523 K, the activation energy of coke sample is the largest. After adding coal, the activation energy of the sample is significantly reduced. It shows that the reactivity of the sample becomes larger after adding coal.

At the same time, it can be seen that the activation energy in the temperature range of 1223 K~1373 K is generally greater than it in the temperature range of 1373 K~1523 K. This suggests that the carbon solution loss reaction in the temperature range of 1373 K~1523 K is more vigorous. In the temperature range of 1223 K~1373 K, the activation energy of samples reduced with the increase of the content of the pulverized coal, and the activation energy of samples added in 2#coal had the greater decrease. The results show that the different volatile contents of the coal have significant influence on the activation energy of the gasification reaction between pulverized coal and CO2, and the higher volatile content, the smaller the activation energy. In the temperature range of 1373 K~1523 K, the activation

Figure 3 Relationship between reaction activation energy and the additive amount of coal
Figure 3

Relationship between reaction activation energy and the additive amount of coal

energy also reduced with the increase of the content of the pulverized coal, but the extent of decrease was not obvious, and the activation energy of samples added two coals was nearly. This is because when the reaction was carried out above 1373 K, the pulverized coal of reaction was gradually consumed, and more and more coke powders involved in the reaction. Especially to the samples added 2# coal, since the high volatile of the coal and the low content of fixed carbon, when the reaction proceeded to certain extent, the amount of coke participating in the reaction increased, and the reaction activation energy of the sample became larger slightly.

3.3 Kinetics model of gasification reaction

In smelting process of blast furnace, the unburned pulverized coal was brought to the cohesive zone with the rising gas. As the small granularity, huge specific surface area, the high reactivity with CO2, so the unburned pulverized coal will react with CO2 ahead of the coke. There are two reaction zones of the unburned pulverized coal reacted with CO2: one is in the atmosphere rising along with gas flow at a certain temperature, and the alternative is in the surface of the coke and ore. Some of the unburned pulverized coal can be attached to the surface of the coke and ore through the gas stream and react with CO2 in these places.

For gas-solid reaction, there are varieties of kinetic models in the field of metallurgy [19, 20]. For the solid blocks or the blocks with low porosity and the solid materials with the big difference of reactivity between the kernel and the interface,we usually use the unreacted core model. The unreacted core model is a non-catalytic gas-solid reaction model. During the reaction, the particle size does not change, and the core does not react, but the reaction interface continues to push toward the core. For the solid materials with high porosity or the ore balls, we usually use the porous volume-reacted model. In porous volume-reacted model, while the reactive gases are diffused into the solid materials with high porosity, they also take place the chemical reaction in the pore. That is to say, the diffusion and the chemical reaction are processed simultaneously. When the unburned pulverized coal is attached to the surface of the porous coke, the model of coke solution loss reaction is shown in Figure 4.

Figure 4 Gasification reaction model of coke blocks attached the unburnt pulverized coal
Figure 4

Gasification reaction model of coke blocks attached the unburnt pulverized coal

CO2 in the furnace gas can diffuse into the interior of coke. The gasification reaction is carried out not only on the surface but also inside coke and it is processed with the gas diffusion at the same time. Generally, when the temperature is low, the restrictive link is chemical reaction and CO2 can be sufficiently diffused into the interior of the porous coke. When the temperature rises, the reaction rate becomes large, CO2 diffusion only to a certain depth, and the reaction will be carried out within a certain radius. When the temperature is higher, the chemical reaction rate is very high, and CO2 is almost completely consumed on the surface of the coke, the reaction performed only on the surface [21, 22]. When the coke blocks attached the unburned pulverized coal, the reaction of coke-CO2 can be seen as the unreacted core model. The reaction was occurred in the surface adequately, and solution loss of the coke’s kernel is small. Meanwhile, as the uneven attachment of the unburned pulverized coal, a small amount of CO2 can penetrate into the interior of coke through the pores, then the gasification reaction follows the porous volume-reacted model.

4 Conclusion

  1. Weight-loss ratio of samples reacted with CO2 increased after adding pulverized coal, and the weight-loss ratio rose with the increase of coal’s addition.

  2. (2) When the content of pulverized coal was small, the volatile of coal had little influence on the weight-loss ratio of samples;when the content of pulverized coal was 50%, the weight-loss ratio of the sample which added pulverized coal with high volatile was higher under the same temperature.

  3. The activation energy of samples had the largest decrease with 83.408 kJ·mol−1 at the range of 1223 K~1373 K and it was 28.97 kJ·mol−1 at the range of 1373 K~1523 K.

  4. The addition of pulverized coal with high volatile can reduce the reaction activation energy of samples more effectively. Due to the larger reactivity, the unburned pulverized coal of it reacted with CO2 before coke, and the CO2 in the atmosphere was consumed simultaneously. So the appropriate pulverized coal injection with high volatile can cut down the coke degradation in blast furnace.

  5. Near the soft melting zone, the gasification reaction model of coke blocks attached the unburned pulverized coalwas up to unreacted core model and porous volume-reacted model jointly.

Acknowledgement

This study was supported by the National Natural Science Foundation of China (51364030), the Scientific Research Foundation of the Higher Education Institutions of Inner Mongolia Autonomous Region (NJZZ19123), and the Natural Science Foundation of Inner Mongolia Autonomous Region of china.

List of symbols

β

Heating rate, β=dTdt

dαdt

Reaction rate

A

Pre-exponential factor

E

Reaction activation energy

f(α)

Weightlessness function

k

Constant of reaction rate

n

Reaction order

R

Ideal gas constant, 8.314 J/K·mol

ω0

Sample mass before reaction

ω

Residual mass after reaction

ωt

Sample mass at time t

T0

Initial reaction temperature

References

[1] L. Lu, V. Sahajwalla, and D. Harris, Metall. Mater. Trans. B., 32(5) (2001) 811-820.10.1007/s11661-001-1016-7Search in Google Scholar

[2] J.K. Chung, J.W. Han, and J.H. Lee, Met. Mater. Int., 2(1) (1996) 1-7.10.1007/BF03025940Search in Google Scholar

[3] Y.F. Chai, J.L. Zhang, Q.J. Shao, X.J. Ning, and K.D. Wang, High Temp. Mater. Processes, 38 (2019) 42-49.10.1515/htmp-2017-0141Search in Google Scholar

[4] W.R.Xu, K.Wu, L.L.Zhang, Y.Zhao, F.Zhang, Iron and Steel, 41(4) (2006) 10-14.Search in Google Scholar

[5] T. Zheng, K. Wu, W.R. Xu, R.L. Zhu, and W.Z. Jiang, Iron and Steel, 41(3) (2006) 20-24.Search in Google Scholar

[6] Q. Zhang, J.H. Yang, Y.L. Li, Coal Convers., 25(1) (2002) 62-66.Search in Google Scholar

[7] J.H. Yang, A.Z. Feng, and H.G. Du, Iron and Steel, 36(6) (2001) 5-9.Search in Google Scholar

[8] H. Bertling, ISIJ Int., 39(7) (1999) 617-624.10.2355/isijinternational.39.617Search in Google Scholar

[9] B. Chakraborty, B.N. Prasad, N.K. Ghosh, L. Parthasarathy, ISIJ Int., 38(8) (1998) 807-811.10.2355/isijinternational.38.807Search in Google Scholar

[10] M. Lundgren, R. Khanna, L.S. Ökvist, V. Sahajwalla, and B. Björk-man, Metall. Mater. Trans. B. 45(2) (2014) 603-616.10.1007/s11663-013-9977-7Search in Google Scholar

[11] J. Hu, F.S. Kong, X.M. Zhao, J.H. Song, and J.L. Zhang, J. China Coal Soc., 28(4) (2003) 419-422.10.1023/A:1022888332221Search in Google Scholar

[12] D.S. Hu and W.Z. Sun, The 9th China Steel Conference, October 23-25, 2013, The Chinese Society for Metals, Beijing, Metallurgical Industry Press, (2013), pp. 1-6.Search in Google Scholar

[13] A.W. Coats and J.P. Redfern, Nature, 201 (1964) 68-69.10.1038/201068a0Search in Google Scholar

[14] M.J. Starink, Thermochim. Acta, 404(1-2) (2003) 163-176.10.1016/S0040-6031(03)00144-8Search in Google Scholar

[15] J.R. Maccallum, J.Tanner, Eur. Polym. J., 6(6) (1970) 907-917.10.1016/0014-3057(70)90014-5Search in Google Scholar

[16] R.E. Kahrizsangi and M.H. Abbasi, T. Nonferr. Metal. Soc., 18(1) (2008) 217-221.10.1016/S1003-6326(08)60039-4Search in Google Scholar

[17] J. Zhou, Z.J. Zhou, X. Gong, and Z.H. Yu, Coal Convers., 25(04) (2002) 66-67.Search in Google Scholar

[18] J. Zhou, Z.J. Zhou, X. Gong, and Z.H. Yu, Coal Convers., 26(1) (2003) 78-81.Search in Google Scholar

[19] X.H. Huang, Principle of Iron and Steel Metallurgy, Metallurgical Industry Press, Beijing, (2013).Search in Google Scholar

[20] H.J. Guo, Tutorials of Physical Chemistry in Metallurgy, Metallurgical Industry Press, Beijing, (2010).Search in Google Scholar

[21] R. Guo and Q.Wang, Metall. Res. Technol., 109(6) (2012) 443-452.10.1051/metal/2012039Search in Google Scholar

[22] Q. Wang, Angang Technol., 383 (2013) 1-8.Search in Google Scholar

Received: 2019-03-29
Accepted: 2019-04-21
Published Online: 2019-07-20
Published in Print: 2019-02-25

© 2019 Yi-fan Chai et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 Public License.

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  65. Controllability of joint integrity and mechanical properties of friction stir welded 6061-T6 aluminum and AZ31B magnesium alloys based on stationary shoulder
  66. Cellular Automaton Modeling of Phase Transformation of U-Nb Alloys during Solidification and Consequent Cooling Process
  67. The effect of MgTiO3Adding on Inclusion Characteristics
  68. Cutting performance of a functionally graded cemented carbide tool prepared by microwave heating and nitriding sintering
  69. Creep behaviour and life assessment of a cast nickel – base superalloy MAR – M247
  70. Failure mechanism and acoustic emission signal characteristics of coatings under the condition of impact indentation
  71. Reducing Surface Cracks and Improving Cleanliness of H-Beam Blanks in Continuous Casting — Improving continuous casting of H-beam blanks
  72. Rhodium influence on the microstructure and oxidation behaviour of aluminide coatings deposited on pure nickel and nickel based superalloy
  73. The effect of Nb content on precipitates, microstructure and texture of grain oriented silicon steel
  74. Effect of Arc Power on the Wear and High-temperature Oxidation Resistances of Plasma-Sprayed Fe-based Amorphous Coatings
  75. Short Communication
  76. Novel Combined Feeding Approach to Produce Quality Al6061 Composites for Heat Sinks
  77. Research Article
  78. Micromorphology change and microstructure of Cu-P based amorphous filler during heating process
  79. Controlling residual stress and distortion of friction stir welding joint by external stationary shoulder
  80. Research on the ingot shrinkage in the electroslag remelting withdrawal process for 9Cr3Mo roller
  81. Production of Mo2NiB2 Based Hard Alloys by Self-Propagating High-Temperature Synthesis
  82. The Morphology Analysis of Plasma-Sprayed Cast Iron Splats at Different Substrate Temperatures via Fractal Dimension and Circularity Methods
  83. A Comparative Study on Johnson–Cook, Modified Johnson–Cook, Modified Zerilli–Armstrong and Arrhenius-Type Constitutive Models to Predict Hot Deformation Behavior of TA2
  84. Dynamic absorption efficiency of paracetamol powder in microwave drying
  85. Preparation and Properties of Blast Furnace Slag Glass Ceramics Containing Cr2O3
  86. Influence of unburned pulverized coal on gasification reaction of coke in blast furnace
  87. Effect of PWHT Conditions on Toughness and Creep Rupture Strength in Modified 9Cr-1Mo Steel Welds
  88. Role of B2O3 on structure and shear-thinning property in CaO–SiO2–Na2O-based mold fluxes
  89. Effect of Acid Slag Treatment on the Inclusions in GCr15 Bearing Steel
  90. Recovery of Iron and Zinc from Blast Furnace Dust Using Iron-Bath Reduction
  91. Phase Analysis and Microstructural Investigations of Ce2Zr2O7 for High-Temperature Coatings on Ni-Base Superalloy Substrates
  92. Combustion Characteristics and Kinetics Study of Pulverized Coal and Semi-Coke
  93. Mechanical and Electrochemical Characterization of Supersolidus Sintered Austenitic Stainless Steel (316 L)
  94. Synthesis and characterization of Cu doped chromium oxide (Cr2O3) thin films
  95. Ladle Nozzle Clogging during casting of Silicon-Steel
  96. Thermodynamics and Industrial Trial on Increasing the Carbon Content at the BOF Endpoint to Produce Ultra-Low Carbon IF Steel by BOF-RH-CSP Process
  97. Research Article
  98. Effect of Boundary Conditions on Residual Stresses and Distortion in 316 Stainless Steel Butt Welded Plate
  99. Numerical Analysis on Effect of Additional Gas Injection on Characteristics around Raceway in Melter Gasifier
  100. Variation on thermal damage rate of granite specimen with thermal cycle treatment
  101. Effects of Fluoride and Sulphate Mineralizers on the Properties of Reconstructed Steel Slag
  102. Effect of Basicity on Precipitation of Spinel Crystals in a CaO-SiO2-MgO-Cr2O3-FeO System
  103. Review Article
  104. Exploitation of Mold Flux for the Ti-bearing Welding Wire Steel ER80-G
  105. Research Article
  106. Furnace heat prediction and control model and its application to large blast furnace
  107. Effects of Different Solid Solution Temperatures on Microstructure and Mechanical Properties of the AA7075 Alloy After T6 Heat Treatment
  108. Study of the Viscosity of a La2O3-SiO2-FeO Slag System
  109. Tensile Deformation and Work Hardening Behaviour of AISI 431 Martensitic Stainless Steel at Elevated Temperatures
  110. The Effectiveness of Reinforcement and Processing on Mechanical Properties, Wear Behavior and Damping Response of Aluminum Matrix Composites
https://doi.org/10.1515/htmp-2019-0016
Keywords for this article
unburnt pulverized coal; coke; carbon solution loss reaction; reactivity; kinetics
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Articles in the same Issue

  1. Frontmatter
  2. Review Article
  3. Research on the Influence of Furnace Structure on Copper Cooling Stave Life
  4. Influence of High Temperature Oxidation on Hydrogen Absorption and Degradation of Zircaloy-2 and Zr 700 Alloys
  5. Correlation between Travel Speed, Microstructure, Mechanical Properties and Wear Characteristics of Ni-Based Hardfaced Deposits over 316LN Austenitic Stainless Steel
  6. Factors Influencing Gas Generation Behaviours of Lump Coal Used in COREX Gasifier
  7. Experiment Research on Pulverized Coal Combustion in the Tuyere of Oxygen Blast Furnace
  8. Phosphate Capacities of CaO–FeO–SiO2–Al2O3/Na2O/TiO2 Slags
  9. Microstructure and Interface Bonding Strength of WC-10Ni/NiCrBSi Composite Coating by Vacuum Brazing
  10. Refill Friction Stir Spot Welding of Dissimilar 6061/7075 Aluminum Alloy
  11. Solvothermal Synthesis and Magnetic Properties of Monodisperse Ni0.5Zn0.5Fe2O4 Hollow Nanospheres
  12. On the Capability of Logarithmic-Power Model for Prediction of Hot Deformation Behavior of Alloy 800H at High Strain Rates
  13. 3D Heat Conductivity Model of Mold Based on Node Temperature Inheritance
  14. 3D Microstructure and Micromechanical Properties of Minerals in Vanadium-Titanium Sinter
  15. Effect of Martensite Structure and Carbide Precipitates on Mechanical Properties of Cr-Mo Alloy Steel with Different Cooling Rate
  16. The Interaction between Erosion Particle and Gas Stream in High Temperature Gas Burner Rig for Thermal Barrier Coatings
  17. Permittivity Study of a CuCl Residue at 13–450 °C and Elucidation of the Microwave Intensification Mechanism for Its Dechlorination
  18. Study on Carbothermal Reduction of Titania in Molten Iron
  19. The Sequence of the Phase Growth during Diffusion in Ti-Based Systems
  20. Growth Kinetics of CoB–Co2B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field
  21. High-Temperature Flow Behaviour and Constitutive Equations for a TC17 Titanium Alloy
  22. Research on Three-Roll Screw Rolling Process for Ti6Al4V Titanium Alloy Bar
  23. Continuous Cooling Transformation of Undeformed and Deformed High Strength Crack-Arrest Steel Plates for Large Container Ships
  24. Formation Mechanism and Influence Factors of the Sticker between Solidified Shell and Mold in Continuous Casting of Steel
  25. Casting Defects in Transition Layer of Cu/Al Composite Castings Prepared Using Pouring Aluminum Method and Their Formation Mechanism
  26. Effect of Current on Segregation and Inclusions Characteristics of Dual Alloy Ingot Processed by Electroslag Remelting
  27. Investigation of Growth Kinetics of Fe2B Layers on AISI 1518 Steel by the Integral Method
  28. Microstructural Evolution and Phase Transformation on the X-Y Surface of Inconel 718 Ni-Based Alloys Fabricated by Selective Laser Melting under Different Heat Treatment
  29. Characterization of Mn-Doped Co3O4 Thin Films Prepared by Sol Gel-Based Dip-Coating Process
  30. Deposition Characteristics of Multitrack Overlayby Plasma Transferred Arc Welding on SS316Lwith Co-Cr Based Alloy – Influence ofProcess Parameters
  31. Elastic Moduli and Elastic Constants of Alloy AuCuSi With FCC Structure Under Pressure
  32. Effect of Cl on Softening and Melting Behaviors of BF Burden
  33. Effect of MgO Injection on Smelting in a Blast Furnace
  34. Structural Characteristics and Hydration Kinetics of Oxidized Steel Slag in a CaO-FeO-SiO2-MgO System
  35. Optimization of Microwave-Assisted Oxidation Roasting of Oxide–Sulphide Zinc Ore with Addition of Manganese Dioxide Using Response Surface Methodology
  36. Hydraulic Study of Bubble Migration in Liquid Titanium Alloy Melt during Vertical Centrifugal Casting Process
  37. Investigation on Double Wire Metal Inert Gas Welding of A7N01-T4 Aluminum Alloy in High-Speed Welding
  38. Oxidation Behaviour of Welded ASTM-SA210 GrA1 Boiler Tube Steels under Cyclic Conditions at 900°C in Air
  39. Study on the Evolution of Damage Degradation at Different Temperatures and Strain Rates for Ti-6Al-4V Alloy
  40. Pack-Boriding of Pure Iron with Powder Mixtures Containing ZrB2
  41. Evolution of Interfacial Features of MnO-SiO2 Type Inclusions/Steel Matrix during Isothermal Heating at Low Temperatures
  42. Effect of MgO/Al2O3 Ratio on Viscosity of Blast Furnace Primary Slag
  43. The Microstructure and Property of the Heat Affected zone in C-Mn Steel Treated by Rare Earth
  44. Microwave-Assisted Molten-Salt Facile Synthesis of Chromium Carbide (Cr3C2) Coatings on the Diamond Particles
  45. Effects of B on the Hot Ductility of Fe-36Ni Invar Alloy
  46. Impurity Distribution after Solidification of Hypereutectic Al-Si Melts and Eutectic Al-Si Melt
  47. Induced Electro-Deposition of High Melting-Point Phases on MgO–C Refractory in CaO–Al2O3–SiO2 – (MgO) Slag at 1773 K
  48. Microstructure and Mechanical Properties of 14Cr-ODS Steels with Zr Addition
  49. A Review of Boron-Rich Silicon Borides Basedon Thermodynamic Stability and Transport Properties of High-Temperature Thermoelectric Materials
  50. Siliceous Manganese Ore from Eastern India:A Potential Resource for Ferrosilicon-Manganese Production
  51. A Strain-Compensated Constitutive Model for Describing the Hot Compressive Deformation Behaviors of an Aged Inconel 718 Superalloy
  52. Surface Alloys of 0.45 C Carbon Steel Produced by High Current Pulsed Electron Beam
  53. Deformation Behavior and Processing Map during Isothermal Hot Compression of 49MnVS3 Non-Quenched and Tempered Steel
  54. A Constitutive Equation for Predicting Elevated Temperature Flow Behavior of BFe10-1-2 Cupronickel Alloy through Double Multiple Nonlinear Regression
  55. Oxidation Behavior of Ferritic Steel T22 Exposed to Supercritical Water
  56. A Multi Scale Strategy for Simulation of Microstructural Evolutions in Friction Stir Welding of Duplex Titanium Alloy
  57. Partition Behavior of Alloying Elements in Nickel-Based Alloys and Their Activity Interaction Parameters and Infinite Dilution Activity Coefficients
  58. Influence of Heating on Tensile Physical-Mechanical Properties of Granite
  59. Comparison of Al-Zn-Mg Alloy P-MIG Welded Joints Filled with Different Wires
  60. Microstructure and Mechanical Properties of Thick Plate Friction Stir Welds for 6082-T6 Aluminum Alloy
  61. Research Article
  62. Kinetics of oxide scale growth on a (Ti, Mo)5Si3 based oxidation resistant Mo-Ti-Si alloy at 900-1300C
  63. Calorimetric study on Bi-Cu-Sn alloys
  64. Mineralogical Phase of Slag and Its Effect on Dephosphorization during Converter Steelmaking Using Slag-Remaining Technology
  65. Controllability of joint integrity and mechanical properties of friction stir welded 6061-T6 aluminum and AZ31B magnesium alloys based on stationary shoulder
  66. Cellular Automaton Modeling of Phase Transformation of U-Nb Alloys during Solidification and Consequent Cooling Process
  67. The effect of MgTiO3Adding on Inclusion Characteristics
  68. Cutting performance of a functionally graded cemented carbide tool prepared by microwave heating and nitriding sintering
  69. Creep behaviour and life assessment of a cast nickel – base superalloy MAR – M247
  70. Failure mechanism and acoustic emission signal characteristics of coatings under the condition of impact indentation
  71. Reducing Surface Cracks and Improving Cleanliness of H-Beam Blanks in Continuous Casting — Improving continuous casting of H-beam blanks
  72. Rhodium influence on the microstructure and oxidation behaviour of aluminide coatings deposited on pure nickel and nickel based superalloy
  73. The effect of Nb content on precipitates, microstructure and texture of grain oriented silicon steel
  74. Effect of Arc Power on the Wear and High-temperature Oxidation Resistances of Plasma-Sprayed Fe-based Amorphous Coatings
  75. Short Communication
  76. Novel Combined Feeding Approach to Produce Quality Al6061 Composites for Heat Sinks
  77. Research Article
  78. Micromorphology change and microstructure of Cu-P based amorphous filler during heating process
  79. Controlling residual stress and distortion of friction stir welding joint by external stationary shoulder
  80. Research on the ingot shrinkage in the electroslag remelting withdrawal process for 9Cr3Mo roller
  81. Production of Mo2NiB2 Based Hard Alloys by Self-Propagating High-Temperature Synthesis
  82. The Morphology Analysis of Plasma-Sprayed Cast Iron Splats at Different Substrate Temperatures via Fractal Dimension and Circularity Methods
  83. A Comparative Study on Johnson–Cook, Modified Johnson–Cook, Modified Zerilli–Armstrong and Arrhenius-Type Constitutive Models to Predict Hot Deformation Behavior of TA2
  84. Dynamic absorption efficiency of paracetamol powder in microwave drying
  85. Preparation and Properties of Blast Furnace Slag Glass Ceramics Containing Cr2O3
  86. Influence of unburned pulverized coal on gasification reaction of coke in blast furnace
  87. Effect of PWHT Conditions on Toughness and Creep Rupture Strength in Modified 9Cr-1Mo Steel Welds
  88. Role of B2O3 on structure and shear-thinning property in CaO–SiO2–Na2O-based mold fluxes
  89. Effect of Acid Slag Treatment on the Inclusions in GCr15 Bearing Steel
  90. Recovery of Iron and Zinc from Blast Furnace Dust Using Iron-Bath Reduction
  91. Phase Analysis and Microstructural Investigations of Ce2Zr2O7 for High-Temperature Coatings on Ni-Base Superalloy Substrates
  92. Combustion Characteristics and Kinetics Study of Pulverized Coal and Semi-Coke
  93. Mechanical and Electrochemical Characterization of Supersolidus Sintered Austenitic Stainless Steel (316 L)
  94. Synthesis and characterization of Cu doped chromium oxide (Cr2O3) thin films
  95. Ladle Nozzle Clogging during casting of Silicon-Steel
  96. Thermodynamics and Industrial Trial on Increasing the Carbon Content at the BOF Endpoint to Produce Ultra-Low Carbon IF Steel by BOF-RH-CSP Process
  97. Research Article
  98. Effect of Boundary Conditions on Residual Stresses and Distortion in 316 Stainless Steel Butt Welded Plate
  99. Numerical Analysis on Effect of Additional Gas Injection on Characteristics around Raceway in Melter Gasifier
  100. Variation on thermal damage rate of granite specimen with thermal cycle treatment
  101. Effects of Fluoride and Sulphate Mineralizers on the Properties of Reconstructed Steel Slag
  102. Effect of Basicity on Precipitation of Spinel Crystals in a CaO-SiO2-MgO-Cr2O3-FeO System
  103. Review Article
  104. Exploitation of Mold Flux for the Ti-bearing Welding Wire Steel ER80-G
  105. Research Article
  106. Furnace heat prediction and control model and its application to large blast furnace
  107. Effects of Different Solid Solution Temperatures on Microstructure and Mechanical Properties of the AA7075 Alloy After T6 Heat Treatment
  108. Study of the Viscosity of a La2O3-SiO2-FeO Slag System
  109. Tensile Deformation and Work Hardening Behaviour of AISI 431 Martensitic Stainless Steel at Elevated Temperatures
  110. The Effectiveness of Reinforcement and Processing on Mechanical Properties, Wear Behavior and Damping Response of Aluminum Matrix Composites
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