Your search keyword '"heating rate"' showing total 113 results

1. The Effect of Heating Rate on the Microstructure Evolution and Hardness of Heterogeneous Manganese Steel.

Author

Ren, Wubin, Zhao, Peiyu, Wang, Menghu, Tong, Shuai, Liang, Xiaokai, Sun, Xinjun, and Wu, Huibin

Subjects

*MANGANESE steel, *TRANSMISSION electron microscopy, *DISLOCATION density, *CEMENTITE, *SCANNING electron microscopy

Abstract

The use of a rapid heating method to achieve heterogeneity of Mn in medium-manganese steel and improve its comprehensive performance has been widely studied and these techniques have been widely applied. However, the heating rate (from α to γ) has not received sufficient attention with respect to its microstructure-evolution mechanism. In this study, the effect of heating rate on the microstructure evolution and hardness of heterogeneous medium-manganese steel was investigated by using X-ray diffraction (XRD), scanning electron microscopy (SEM), electron backscatter diffraction (EBSD), transmission electron microscopy (TEM) and DICTRA simulation. The results showed that the Mn distribution was heterogeneous in the initial microstructure of pearlite due to strong partitioning of Mn between ferrite and cementite. At low heating rates (<10 °C/s), the heterogeneity of Mn distribution was diminished to some extent due to the long-distance diffusion of Mn in high-temperature austenite. Contrastingly, at high heating rates, the initial heterogeneity of the Mn element could be largely preserved due to insufficient diffusion of Mn, which resulted in more ghost pearlite (GP: pearlite-like microstructure with film martensite/RA). Moreover, the high heating rate not only refines the prior austenite grain but also increases the total RA content, which is mainly composed of additional film RA. As the heating rate increases, the hardness gradually increases from 628.1 HV to 663.3 HV, due to grain refinement and increased dislocation density. Dynamic simulations have also demonstrated a strong correlation between this interesting microstructure and the non-equilibrium diffusion of Mn. [ABSTRACT FROM AUTHOR]

Published

2024

2. The Pyrolysis Characteristics of Bagasse Were Studied by TG-MS-FTIR.

Author

Zhang, Songsong, Gao, Yue, Tong, Haichuan, Dong, Yong, Qi, Guoli, and Wang, Peng

Subjects

SUGAR crops, WASTE gases, ENVIRONMENTAL protection, HEAT transfer, SMALL molecules, BAGASSE

Abstract

Sugarcane bagasse is rich in cellulose and lignin, and the recycling of bagasse has become an important research field with the increasing global concern for sustainable development and environmental protection. In this paper, TG-MS-FTIR equipment was used to analyze the pyrolysis characteristics of bagasse from Guangxi under different heating rates and different atmospheres, which is conducive to the reuse of bagasse from the waste gas produced in the sugar plant. The results showed that the pyrolysis rate of sugarcane bagasse in the air atmosphere was faster than that in the nitrogen atmosphere and showed a double-peak trend, and the Coats–Redfern computational model could more accurately simulate the process of pyrolysis. The lower heating rate could overcome the heat transfer hysteresis phenomenon in the process of pyrolysis. In the air atmosphere, the contact time between oxygen and volatile products was shorter due to the high heating rate, and more and more complex species were precipitated at 10 °C/min than at 20 °C/min. In the nitrogen atmosphere, it was favorable to produce more kinds and quantities of gas products, because it did not react with oxygen. FTIR detected CH4, CO, H2O, CO2, C-O-C, and C=O during pyrolysis in nitrogen, and some of C-O-C and C=O were cracked into small molecule compounds at high temperature. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effect of Heating Rate on Hydride Reorientation Behavior of Zirconium Alloy Tubes under Non-Stress Loading.

Author

Hui, Boning, Chen, Mingju, Li, Xinyi, Chen, Biao, Li, Yuli, Zhou, Jun, Tang, Rongtao, and Li, Jinshan

Subjects

STRAINS & stresses (Mechanics), NUCLEAR reactor materials, HEAT conduction, CRACK propagation (Fracture mechanics), COMMON sense, ZIRCONIUM alloys, NUCLEAR fuel claddings

Abstract

Zirconium alloys are widely used in nuclear water reactors as cladding materials. The cladding materials will absorb hydrogen from high temperature water during the operation of nuclear reactor. In cladding tubes, it has been common sense that circumferential hydrides form without stress, while radial hydrides can form when the hydrides are reoriented under stress loading. In this study, we found that a high heating rate can result in hydride reorientation behavior even without stress. At elevated heating rates, the zirconium alloy clad tube developed a non-uniform strain gradient along the direction of heat conduction. Hydrogen atoms migrate preferentially to areas of elevated stress and precipitate as hydrides that are perpendicular to the direction of tensile stress, resulting in the formation of radial hydrides that appear as "sun spots" macroscopically. Additionally, the high heating rate disrupts the {0001}α∥{111}δ, <11–20>α∥<110>δ orientation relationship between the hydride and the substrate, which potentially facilitates crack propagation. [ABSTRACT FROM AUTHOR]

Published

2024

4. Effect of Heating Rate on Microstructure and Corrosion Resistance of Quenched and Tempered 8620 Low Carbon Alloy Steel.

Author

Tajmiri, Sina, Haider, Waseem, and Shabib, Ishraq

Subjects

MICROSTRUCTURE, CORROSION resistance, METAL quenching, MILD steel, HEATING

Abstract

In the process of heat treatment of 8620 low alloy steel, the heating rate is a critical parameter that must be carefully controlled to achieve the desired combination of microstructural features, mechanical properties, and corrosion resistance while simultaneously ensuring process efficiency and cost-effectiveness. This study investigates, for the first time, the microstructural evolution and electrochemical properties of 8620 steel under identical quenching and tempering heat treatment routes with slow-rate (SR) and fast-rate (FR) heating rates. Microstructural analysis revealed martensitic phases for SR, while FR exhibited a dual-phase microstructure containing ferrite. Upon tempering, for both samples, the martensite transformed into tempered martensite, with tempered (Temp) FR exhibiting around 50% smaller ferrite grains. Mechanical testing indicated that SR had 17% higher hardness than FR, although hardness decreased after tempering by 22% (SR) and 17% (FR). All electrochemical tests indicated that the as-quenched SR exhibited significantly superior corrosion resistance than FR. For instance, the polarization resistance of SR was 440 Ω higher than that of the FR samples. Tempering resulted in a considerable decrease in corrosion resistance for Temp SR, whereas Temp FR improved. Electrochemical characterization revealed Temp FR displayed close-to-ideal capacitive behavior and low double-layer capacitance, indicating enhanced overall corrosion resistance. [ABSTRACT FROM AUTHOR]

Published

2024

5. The Effect of Heat Aging on the Microstructure and Properties of Spray-Deposited AlZnMgCu Alloy Extruded Plates.

Author

Chen, Chen, Feng, Di, He, Zhiping, Zhu, Yichao, Tao, Zhiyuan, Xu, Yinhui, Wang, Haoran, Wang, Jingtao, and Liu, Ying

Subjects

*HEAT treatment, *ALLOY plating, *ELECTRIC conductivity, *TRANSMISSION electron microscopy, *CORROSION resistance

Abstract

The heat-aging process, a practical aging technology that not only improves the comprehensive performance of Al alloys but also reflects the requirements of short processes, has an extremely practical significance. The effects of the heating rate and termination temperature on the "heat-aging" behavior of a spray-deposited AlZnMgCu alloy hot-extruded plate were investigated using hardness, electrical conductivity, room-temperature tensile strength, exfoliation corrosion experiments, and transmission electron microscopy microstructure (TEM) observation. The results show that as the termination temperature increases, the hardness of the spray-deposited AlZnMgCu alloy first increases to a peak and then rapidly decreases, while the electrical conductivity continues to increase. The increase in the heating rate improves the peak hardness corresponding to the termination temperature. The heat treatment process of heating at a speed of 20 °C/h to 200 °C after the spray deposition has similar mechanical and corrosion resistance properties to the RRA process and can effectively reduce the heating time from 40 h to 8 h, thus establishing a heat treatment process for spray-deposited AlZnMgCu alloy extruded plate with high aging efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

6. Austenite Growth Behavior and Prediction Modeling of Ti Microalloyed Steel.

Author

Wang, Jun, Liu, Man, Wang, Lifan, He, Ping, Hu, Haijiang, and Xu, Guang

Subjects

*TRANSMISSION electron microscopes, *AUSTENITE, *PREDICTION models, *SCANNING electron microscopes, *GRAIN size, *STEEL

Abstract

Previous studies on the austenite grain growth were mostly based on a fixed temperature, and the relationship between the austenite grain and austenitizing parameters was fitted according to the results. However, there is a lack of quantitative research on the austenite grain growth during the heating process. In the present work, based on the diffusion principle of the controlled Ti microalloying element, the diffusion process of carbonitrides containing Ti during the heating process was analyzed. Combined with the precipitation model and the austenite growth model, the prediction model of austenite grain growth of Ti microalloyed steel during different heat treatment processes was established. The austenite grain size versus the temperature at four different heating rates of 0.5, 1, 10, 100 °C/s was calculated. The grain growth behavior of austenite during the heating process of Ti microalloyed steel was studied by optical microscope, scanning electron microscope and transmission electron microscope. The experimental data of the austenite grain size was in good agreement with the calculation by the proposed model, which provides a new idea for the prediction of austenite grain size in non-equilibrium state during the heating process. In addition, for Ti-containing microalloyed steels, the austenite grain size increased with the increasing heating temperature, while it changed little by further prolonging isothermal time after certain heating time, which was related to the equilibrium degree of the precipitation and the dissolution of Ti element. The austenite grain coarsening temperature of the tested Ti microalloyed steel was estimated within 1100~1200 °C. [ABSTRACT FROM AUTHOR]

Published

2024

7. Fire Resistance of Ultra-High-Strength Steel Columns Using Different Heating Rates.

Author

Piloto, Paulo A. G., Pereira, Arthur Silva, and Mottin, Artur Caron

Subjects

IRON & steel columns, SUSTAINABLE construction, SUSTAINABLE engineering, CREEP (Materials), CARBON steel, COMPOSITE columns

Abstract

Featured Application: Numerical results to determine the fire resistance of ultra-high-strength steel using different heating rates. Ultra-High-Strength Steel (UHSS) offers several advantages over normal carbon steel, promoting exceptional strength, reducing self-weight, improving fire resistance, enhancing durability, and reducing material consumption. These advantages result in cost savings and sustainable engineering construction. The 3D numerical model is based on Geometrical and Materially Nonlinear Imperfection Analysis (GMNIA) and determines the fire resistance of different cross-section columns. The model is validated with experimental tests, with a maximum relative error of 11%. A parametric analysis is presented, based on 252 simulations, assuming three heating rates, two different cross-sections, two different thicknesses, three lengths, and seven load levels. The fire resistance depends on the heating rate, but the critical temperature is almost equal and independent of the heating rate, if one assumes implicit creep in the constitutive material model. The fire resistance decreases with the load level, as expected. The thickness effect of the hollow section is almost negligible in the fire resistance of UHSS columns. The fire resistance decreases more in higher load levels for slender columns. Columns with Circular Hollow Sections (CHSs) generally show higher fire resistance than hybrid columns in longer columns, but the hybrid columns are subject to much higher loads. New design formulas are presented for the critical temperature of UHSS columns, depending on the load level and slenderness of two different cross-sections. [ABSTRACT FROM AUTHOR]

Published

2024

8. Influences of the Decomposition Atmosphere and Heating Rate on the Pyrolysis Behaviors of Resin Sand.

Author

Xu, Qingwei, Zhu, Yaping, Xu, Kaili, Li, Bingjun, and Su, Nan

Subjects

SAND, FOUNDRY sand, SAND casting, PYROLYSIS, HEAT conduction, ATMOSPHERIC nitrogen, ACTIVATION energy

Abstract

The pouring of sand casting is accompanied by severe heat conduction, and there is an urgent need to investigate the pyrolysis properties of foundry sand. The main purpose of this study was to investigate the pyrolysis behaviors of resin sand, including precoated sand (PCS), hot box sand (HBS), and warm box sand (WBS), at heating rates of 20 °C/min, 30 °C/min, and 40 °C/min in nitrogen and air atmospheres. The mass loss of the resin sand was monitored continuously with a simultaneous thermal analyzer, and the kinetic parameters of the resin sand were calculated based on the Coats–Redfern method and thermal data. The average mass loss of the resin sand during pyrolysis was 3.03%, which was much smaller than that of the other sands. The volatile release characteristic index of resin sand could not be calculated based on this concept. To solve this issue, the term Tstv/mloss was established, and its value was determined. With increasing heating rates from 20 °C/min to 30 °C/min and from 30 °C/min to 40 °C/min, the mass losses of the resin sand increased by 0.79% and 0.64%, respectively, and the volatile release characteristic indices of the resin sand increased by 3.8 × 10−10 and 1.06 × 10−9, respectively. In addition, the mass losses and volatile release characteristic indices of resin sand in an air atmosphere were greater than those in a nitrogen atmosphere. With increasing heating rate, the activation energy of the resin sand decreased in a nitrogen atmosphere. The findings concerning the thermal decomposition behaviors of resin sand provided a theoretical basis for the pouring step of the sand casting process. [ABSTRACT FROM AUTHOR]

Published

2024

9. Synergistic Effects and Kinetic Analysis in Co-Pyrolysis of Peanut Shells and Polypropylene.

Author

Huang, Zhigang, Wu, Jiahui, Yang, Tenglun, Wang, Zihan, Zhang, Tong, Gao, Fei, Yang, Li, and Li, Gang

Subjects

PEANUT hulls, WASTE recycling, PLASTIC scrap, POLYPROPYLENE, ACTIVATION energy, THERMOGRAVIMETRY

Abstract

The impact of COVID-19 has boosted growth in the takeaway and medical industries but has also generated a large amount of plastic waste. Peanut shells (PS) are produced in large quantities and are challenging to recycle in China. Co-pyrolysis of peanut shells (PS) and polypropylene (PP) is an effective method for processing plastic waste and energy mitigation. Thermogravimetric analysis was conducted on PS, PP, and their blends (PS-PP) at different heating rates (10, 20, 30 °C·min−1). The results illustrated that the co-pyrolysis process of PS-PP was divided into two distinct decomposition stages. The first stage (170–400 °C) was predominantly linked to PS decomposition. The second stage (400–520 °C) resulted from the combinations of PS and PP's thermal degradations, with the most contribution from PP degradation. With the increase in heating rate, thermogravimetric hysteresis appeared. Kinetic analysis indicated that the co-pyrolysis process reduced the individual pyrolysis activation energy, especially in the second stage, with a correlation coefficient (R2) generally maintained above 0.95. The multi-level reaction mechanism function model can effectively reveal the co-pyrolysis process mechanism. PS proved to be high-quality biomass for co-pyrolysis with PP, and all mixtures exhibited synergistic effects at a mixing ratio of 1:1 (PS1-PP1). This study accomplished effective waste utilization and optimized energy consumption. It holds significance in determining the interaction mechanism of mixed samples in the co-pyrolysis process. [ABSTRACT FROM AUTHOR]

Published

2024

10. Physical and Mechanical Properties and Damage Mechanism of Sandstone at High Temperatures.

Author

Zheng, Yadong, Zhang, Lianying, Wu, Peng, Guo, Xiaoqian, Li, Ming, and Zhu, Fuqiang

Subjects

HIGH temperatures, SANDSTONE, ROCK properties, ELASTIC modulus, ACOUSTIC emission, SCANNING electron microscopes

Abstract

The physical and mechanical properties of rocks change significantly after being subjected to high temperatures, which poses safety hazards to underground projects such as coal underground gasification. In order to investigate the effect of temperature on the macroscopic and microscopic properties of rocks, this paper has taken sandstone as the research object and conducted uniaxial compression tests on sandstone specimens at different temperatures (20–1000 °C) and different heating rates (5–30 °C/min). At the same time, the acoustic emission (AE) test system was used to observe the acoustic emission characteristics of the rock damage process, and the microstructural changes after high temperature were analyzed with the help of a scanning electron microscope (SEM). The test results show that the effect of temperature on sandstone is mainly divided into three stages: Stage I (20–500 °C) is the strengthening zone, the evaporation of water and the contraction of primary fissures, and sandstone densification is enhanced. In particular, the compressive strength and elastic modulus increase, the macroscopic damage mode is dominated by shear damage, and the fracture micromorphology is mainly brittle fracture. Stage II (500–600 °C) is the transition zone, 500 °C is the threshold temperature for the compressive strength and modulus of elasticity, and the damage mode changes from shear to cleavage damage, and the sandstone undergoes brittle–ductile transition in this temperature interval. Stage III is the physicochemical deterioration stage. The changes in the physical and chemical properties make the sandstone compressive strength and modulus of elasticity continue to decline, the macroscopic damage mode is mainly dominated by cleavage damage, and the fracture microscopic morphology is of a more toughness fracture. The effect of different heating rates on the mechanical properties of sandstone was further studied, and it was found that the mechanical properties of the rock further deteriorated under higher heating rates. [ABSTRACT FROM AUTHOR]

Published

2024

11. Anthropic Settlements' Impact on the Light-Absorbing Aerosol Concentrations and Heating Rate in the Arctic.

Author

Losi, Niccolò, Markuszewski, Piotr, Rigler, Martin, Gregorič, Asta, Močnik, Griša, Drozdowska, Violetta, Makuch, Przemysław, Zielinski, Tymon, Pakszys, Paulina, Kitowska, Małgorzata, Cefalì, Amedeo Manuel, Gini, Irene, Doldi, Andrea, Cerri, Sofia, Maroni, Pietro, Bolzacchini, Ezio, and Ferrero, Luca

Subjects

*AEROSOLS, *HUMAN settlements, *SEA ice, *RADIATIVE forcing, *ARCHIPELAGOES, *ATMOSPHERE

Abstract

Light-absorbing aerosols (LAA) impact the atmosphere by heating it. Their effect in the Arctic was investigated during two summer Arctic oceanographic campaigns (2018 and 2019) around the Svalbard Archipelago in order to unravel the differences between the Arctic background and the local anthropic settlements. Therefore, the LAA heating rate (HR) was experimentally determined. Both the chemical composition and high-resolution measurements highlighted substantial differences between the Arctic Ocean background (average eBC concentration of 11.7 ± 0.1 ng/m3) and the human settlements, among which the most impacting appeared to be Tromsø and Isfjorden (mean eBC of 99.4 ± 3.1 ng/m3). Consequently, the HR in Isfjorden (8.2 × 10−3 ± 0.3 × 10−3 K/day) was one order of magnitude higher than in the pristine background conditions (0.8 × 10−3 ± 0.9 × 10−5 K/day). Therefore, we conclude that the direct climate impact of local LAA sources on the Arctic atmosphere is not negligible and may rise in the future due to ice retreat and enhanced marine traffic. [ABSTRACT FROM AUTHOR]

Published

2023

12. Induction Heating and Cooling Performance of Asphalt Mixture as Recycling Rap and Steel Slag.

Author

Yang, Chao, Lei, Zilin, Wang, Sicheng, Wang, Fusong, Zhou, Wangwang, Luo, Qiuyuan, and Zhang, Jixin

Abstract

Recycling reclaimed asphalt pavement (RAP) for asphalt pavement construction is of interest due to its potential to mitigate environmental impact and resource consumption; however, the addition of RAP limits the induction heating behavior of asphalt mixtures, hindering the further application of RAP in sustainable and functional asphalt pavement. This study prepared recycled asphalt mixtures with high contents of steel slag aggregate and RAP, and optimized the rejuvenator dosage and composition design to investigate the induction heating rate. The effect of the steel fiber content, heating time, and heating distance on the induction capacity were verified for the recycled asphalt mixture. Moreover, the cooling curves of the recycled asphalt mixture were explored using a constant temperature chamber and infrared camera. The results showed that 6 wt% of rejuvenator in aged asphalt could evidently restore the physical properties and surface morphology, the highest heating rate of 1.204 °C/s could be reached with 2 wt% of steel fiber content, and the effective intervals of heating time and heating distance were set as 60–120 s and 10–20 mm, respectively. This study could be a significant reference in promoting solid waste recycling and sustainable asphalt pavement construction. [ABSTRACT FROM AUTHOR]

Published

2023

13. Effects of Heating Rates on Microstructural Evolution of Hot Extruded 7075 Aluminum Alloy in the Semi-Solid State and Thixotropic Deformation Behavior.

Author

Gu, Guochao, Li, Ruifen, Xiang, Lixin, Xiao, Guiyong, and Lu, Yupeng

Subjects

*STRESS-strain curves, *STRAIN rate, *RHEOLOGY, *CRYSTAL grain boundaries, *DEFORMATIONS (Mechanics)

Abstract

The non-dendritic microstructure plays a crucial role in determining the rheological properties of semi-solid alloys, which are of the utmost importance for the successful industrial application of the thixoforging process. To further understand the impact of the reheating process on the evolution of microstructure and thixotropic deformation behavior in the semi-solid state, a hot extruded and T6 treated 7075 aluminum alloy was reheated to the selected temperature ranges using varying heating rates. Subsequently, thixo-compression tests were performed. The study found that during reheating and isothermal holding, the elongated microstructure of the as-supplied alloy can transform into equiaxed or spherical grains. The presence of recrystallized grains was found to be closely linked to the penetration of the liquid phase into the recrystallized grain boundaries. Furthermore, it was observed that higher heating rates resulted in smaller grain sizes. The thixotropic flow behavior of the alloy with various microstructures was analyzed using the true stress–strain curves obtained by thixo-compression experiments, which exhibited three stages: a rapid increase in true stress to a peak value, followed by a decrease in true stress and a steady stress until the end of compression. The stress fluctuated with strain during the formation of the slurry at a strain rate of 10 s−1, indicating the significant role of strain rate in material flow during semisolid formation. [ABSTRACT FROM AUTHOR]

Published

2023

14. Fast Pyrolysis of Tea Bush, Walnut Shell, and Pine Cone Mixture: Effect of Pyrolysis Parameters on Pyrolysis Crop Yields.

Author

Kar, Turgay, Kaygusuz, Ömer, Güney, Mükrimin Şevket, Cuce, Erdem, Keleş, Sedat, Shaik, Saboor, Owolabi, Abdulhameed Babatunde, Nsafon, Benyoh Emmanuel Kigha, Ogunsua, Johnson Makinwa, and Huh, Jeung-Soo

Abstract

Liquid products obtained by the fast pyrolysis process applied to biomass can be used as chemical raw materials and liquid fuels. In this study, tea bush, walnut shell, and pine cone samples selected as biomass samples were obtained from Trabzon and Rize provinces in the Eastern Black Sea Region and used. When considered in terms of our region, the available biomass waste samples are easy to access and have a high potential in quantity. To employ them in the experimental investigation, these biomass samples were first ground, sieved to a particle size of 1.0 mm, and mixed. A fast pyrolysis process was applied to this obtained biomass mixture in a fixed-bed pyrolysis reactor. The effects of temperature, heating rate, and nitrogen flow rate on the product yields of the fast pyrolysis technique used on the biomass mixture are examined. A constant particle size of 1.0 mm, temperatures of 300, 400, 500, 600, and 750 °C, heating rates of 100, 250, 400, and 600 °C.min−1, and flow rates of 50, 100, 200, and 300 cm3.min−1 were used in tests on fast pyrolysis. The studies showed the 500 °C pyrolysis temperature, 100 °C min−1 heating rate, and 50 cm3.min−1 nitrogen flow rate gave the maximum liquid product yield. The liquid product generated under the most compelling circumstances is analyzed to determine moisture, calorific value, fixed carbon, ash, raw coke, and volatile matter. Additionally, the crude bio-oil heating value, measured at 5900 cal/g and produced under the most favorable pyrolysis circumstances, rose by around 40% compared to its starting material. The liquid product obtained from rapid pyrolysis experiments can be used as liquid fuel. The evaluation of the potential of chemical raw materials can be a subject of research in a different discipline since there are many chemical raw materials (glycerine, furfurals, cellulose and derivatives, carbonaceous materials, and so forth) in fast pyrolysis liquids. [ABSTRACT FROM AUTHOR]

Published

2023

15. MEMS Resonant Cantilevers for High-Performance Thermogravimetric Analysis of Chemical Decomposition.

Author

Cao, Zhi, Jia, Hao, Zhou, Yufan, Li, Ming, Xu, Pengcheng, Li, Xinxin, and Zheng, Dan

Subjects

*CHEMICAL decomposition, *ANALYTICAL chemistry, *THERMOGRAVIMETRY, *CANTILEVERS, *CALCIUM oxalate, *FINITE element method

Abstract

We investigate the MEMS resonant cantilevers for high-performance thermogravimetric analysis (TGA) of chemical decomposition, featuring high accuracy and minimized thermal lag. Each resonant cantilever is integrated with a microheater for sample heating near the free end, which is thermally isolated from the resonance excitation and readout elements at the fixed end. Combining finite element modeling and experiments, we demonstrate that the sample loading region can stabilize within ~11.2 milliseconds in response to a step heating of 500 °C, suggesting a very fast thermal response of the MEMS resonant cantilevers of more than 104 °C/s. Benefiting from such a fast thermal response, we perform high-performance TG measurements on basic copper carbonate (Cu2(OH)2CO3) and calcium oxalate monohydrate (CaC2O4·H2O). The measured weight losses better agree with the theoretical values with 5–10 times smaller thermal lags at the same heating rate, compared with those measured by using conventional TGA. The MEMS resonant cantilevers hold promise for highly accurate and efficient TG characterization of materials in various fields. [ABSTRACT FROM AUTHOR]

Published

2023

16. Study on the Effect of External Air Supply and Temperature Control on Coal Spontaneous Combustion Characteristics.

Author

Lei, Changkui, Shi, Xueqiang, Jiang, Lijuan, Deng, Cunbao, Nian, Jun, and Gao, Yabin

Abstract

Coal spontaneous combustion in underground mine goaf has a great impact on coal mining. The temperature-programmed experiment is a commonly used and effective method for studying the characteristics of coal spontaneous combustion. Aiming at the problem that the numerical simulation of coal spontaneous combustion characteristics under the condition of external air supply and temperature control in a temperature-programmed experiment is insufficient, a multi-physical field coupling numerical model of coal spontaneous combustion in the temperature-programmed experiment is established. The variation characteristics of coal temperature, oxygen, and oxidation products under external air supply and temperature control were studied. The results show that the numerical simulation results are consistent with the experimental results. With the increase in temperature, the volume fractions of oxygen and carbon dioxide decrease and increase, respectively. As the air supply volume increases, the oxygen volume fraction at the outlet increases, and the peak value of the oxygen volume fraction change rate exhibits a "hysteresis" feature, and the time corresponding to the peak value increases. Moreover, the temperature change rate increases. With the increase in the heating rate, the peak value of the oxygen volume fraction change rate increases and shows an "early appearance" characteristic, at the same time, the maximum coal temperature displays a linear increase trend. [ABSTRACT FROM AUTHOR]

Published

2023

17. Performance Evaluation of Carbon-Based Nanofluids for Direct Absorption Solar Collector.

Author

Yu, Shang-Pang, Teng, Tun-Ping, Huang, Chia-Cing, Hsieh, Hsiang-Kai, and Wei, Yi-Jia

Subjects

*SOLAR collectors, *NANOFLUIDS, *HEAT storage, *VORTEX methods, *HEAT capacity, *LIGHT sources

Abstract

In this study, carbon-based nanofluids (CBNFs) were prepared using a revised vortex trap method and applied in the direct absorption solar collector (DASC) to evaluate the feasibility of CBNFs in DASC. The thermal storage performance of water and different concentrations of CBNFs (0.01, 0.025 and 0.05 wt%) was assessed with a 1000 W halogen lamp as a simulated light source under different volumetric flow rates (1.5, 3.0, and 4.5 L per minute [LPM]) at a constant thermal storage load (2.4 kg of water) and ambient temperature of 26 °C. The thermal storage capacity, system efficiency factor (SEF), and heating rate of the CBNFs as the working fluid were higher than those of water in most cases. The thermal storage capacity and SEF of 0.05 wt% CBNF at a volumetric flow rate of 3.0 LPM were 10.36% and 9.36% higher than that of water, respectively. The relevant experimental results demonstrate the great potential of CBNFs in DASC. [ABSTRACT FROM AUTHOR]

Published

2023

18. Characteristics of Optical Properties and Heating Rates of Dust Aerosol over Taklimakan Desert and Tibetan Plateau in China Based on CALIPSO and SBDART.

Author

Xu, Xiaofeng, Pan, Shixian, Luo, Tianyang, Yang, Yudi, and Xiong, Zixu

Subjects

*MINERAL dusts, *DUST, *AEROSOLS, *SPRING, *OPTICAL properties, *AUTUMN, *DESERTS

Abstract

The spatial and temporal distributions of dust aerosol and its radiative heating effect over Taklimakan Desert (TD) and Tibetan Plateau (TP) were analyzed using the CALIPSO aerosol products and the SBDART model during 2007–2020. The annual dust aerosol optical depths (DAOD at 532 nm) ranged from 0.266 to 0.318 over TD and 0.086 to 0.108 over TP, with means of 0.286 ± 0.015 and 0.097 ± 0.006, respectively. The regional mean DAODs of TD (TP) from spring to winter were 0.375 ± 0.020 (0.107 ± 0.010), 0.334 ± 0.028 (0.110 ± 0.010), 0.235 ± 0.026 (0.071 ± 0.008), and 0.212 ± 0.045 (0.083 ± 0.011), respectively. The maximal (minimal) seasonal DAOD of TD appeared in spring (winter), while that of TP appeared in summer (autumn). Although neither the annual nor the seasonal DAODs showed a statistically significant trend over both TD and TP, their yearly fluctuations were apparent, showing coefficients of variation of 0.053 and 0.065 over TD and TP, respectively. The profile of dust extinction coefficient (σD) showed the maximum in spring and summer over TD and TP, respectively. It showed a weak increasing trend of σD over both TD and TP in spring, but a decreasing trend in autumn. The dust of TD is concentrated within 1–4 km, where the annual averaged shortwave (SW) dust heating rates (DHRs) were larger than 2 K·day−1 from March to September. Over TP, the dust heating layer with SW DHR > 2 K·day−1 ranged from 3 to 4 km during March to June. The SW DHR was much larger in spring and summer than in the other two seasons over both regions, with the maximum in spring. A relatively strong dust heating layer with top >5 km appeared along the north slope of the TP, indicating an important energy transport channel from TD to TP, especially in spring and summer. It showed an increasing trend of the SW DHR over both TD and TP in spring and winter, but a decreasing trend in summer and autumn. Over TD, the most powerful heating appeared within 2–4 km, but the strength and the area of high-value DHR reduced from spring to winter. The highest SW DHR of TP appeared over the Qaidam Basin, acting as an important transmission channel of dust and its heating. For the columnar mean of lower than 10 km, the annual mean DHRs of TD and TP were 0.93 and 0.48 K⋅day−1, respectively. Although the DAOD and DHR of TP were both lower, its shortwave dust heating efficiency (DHE) was 1.7 times that of TD, which suggested that the same amount of dust imported to TP could generate a stronger heating effect than it did at the source. [ABSTRACT FROM AUTHOR]

Published

2023

19. Heating Rate during Thermal Modification in Steam Atmosphere: Influence on the Properties of Maple and Ash Wood.

Author

Milić, Goran, Todorović, Nebojša, Veizović, Marko, and Popadić, Ranko

Subjects

WOOD ash, MAPLE, WOOD, FLEXURAL strength, EUROPEAN ash, STEAM generators, SWELLING of materials

Abstract

This study aimed to compare two thermal modification (TM) schedules—with short and long heating phases—and their influence on the properties of maple (Acer pseudoplatanus L.) and ash (Fraxinus excelsior L.) wood. Two TM runs were conducted in industrial conditions (open system, steam atmosphere; substantially longer method compared to the processes usually described in the literature), with the same peak phase (200 °C, 3 h), but with different heating rates—slow (1.1 °C/h) and fast (2.5 °C/h). The results revealed that both TMs significantly reduced hygroscopicity and swelling of wood, but the influence of slow heating rate—through prolonged exposure of wood to relatively high temperatures—on dimensional stability was more pronounced. The modulus of elasticity, compressive strength and Brinell hardness remained mostly unchanged after TM (except for fast-modified maple), while the modulus of rupture was strongly reduced by TM in both species. It is assumed—at least in the case of maple wood—that a combination of initial moisture content above 8% and fast heating rate during TM can cause more intensive degradation of wood polymers. Relatively small differences in colour between slow- and fast-modified wood were found. The results confirmed the hypothesis that the heating phase is an important part of the TM schedule, and it can directly affect (together with peak temperature and time) certain wood properties. [ABSTRACT FROM AUTHOR]

Published

2023

20. Experimental Investigation of the Characteristics and Transformation Mechanism of Jimsar Oil Shale and Derived Shale Oil.

Author

Lu, Hao, Pan, Luwei, Guo, Yue, Xiong, Quan, Dai, Fangqin, and Wang, Shuai

Subjects

SHALE oils, OIL shales, GAS chromatography/Mass spectrometry (GC-MS), NMR spectrometers, FOURIER transform infrared spectroscopy, ALIPHATIC compounds

Abstract

An experimental investigation of the characteristics and transformation mechanism of Jimsar oil shale and derived shale oil was conducted using a solid-state nuclear magnetic resonance spectrometer (13C NMR), Fourier transform infrared spectroscopy (FT-IR), liquid 1H NMR, and gas chromatography-mass spectrometry (GC-MS) techniques. The carbon skeleton structure of Jimsar oil shale is mainly composed of aliphatic carbons (70.5%), mostly containing straight-chain methylene (CH2), and aromatic carbon (29.31%). Derived shale oil is primarily made of aliphatic compounds that are dominated by n-alkanes and alkenes (comprising more than 70%). The nature of the conversion of oil shale to shale oil is the decomposition of aliphatic groups dominated by methylene structures in organic matter. Additionally, as the heating rate is increased, the secondary cracking reactions in shale oil could increase the contents of short-chain alkanes and alkenes, which could then enhance the secondary polymerization reactions that increase the generation of cycloalkanes and aromatic compounds. Shale oil demonstrates a maximum yield value of 6.32%, the largest carbon, hydrogen, and nitrogen contents, and a minimum oxygen content at the pyrolysis heating rate of 5 °C/min. [ABSTRACT FROM AUTHOR]

Published

2023

21. Effect of Heating on Hot Deformation and Microstructural Evolution of Ti-6Al-4V Titanium Alloy.

Author

Li, Dechong, Zhu, Haihui, Qu, Shuguang, Lin, Jiatian, Ming, Ming, Chen, Guoqing, Zheng, Kailun, and Liu, Xiaochuan

Subjects

*TITANIUM alloys, *SPECIFIC heat, *PHASE transitions, *TENSILE tests, *LOW temperatures, *GRAIN size

Abstract

This paper presents a systematic study of heating effects on the hot deformation and microstructure of dual-phase titanium alloy Ti-6Al-4V (TC4) under hot forming conditions. Firstly, hot flow behaviors of TC4 were characterized by conducting tensile tests at different heating temperatures ranging from 850 °C to 950 °C and heating rates ranging from 1 to 100 °C/s. Microstructure analysis, including phase and grain size, was carried out under the different heating conditions using SEM and EBSD. The results showed that when the heating temperature was lower than 900 °C, a lower heating rate could promote a larger degree of phase transformation from α to β, thus reducing the flow stress and improving the ductility. When the temperature reached 950 °C, a large heating rate effectively inhibited the grain growth and enhanced the formability. Subsequently, according to the mechanism of phase transformation during heating, a phenomenological phase model was established to predict the evolution of the phase volume fraction at different heating parameters with an error of 5.17%. Finally, a specific resistance heating device incorporated with an air-cooling set-up was designed and manufactured to deform TC4 at different heating parameters to determine its post-form strength. Particularly, the yield strength at the temperature range from 800 °C to 900 °C and the heating rate range from 30 to 100 °C/s were obtained. The results showed that the yield strength generally increased with the increase of heating temperature and the decrease of heating rate, which was believed to be dominated by the phase transformation. [ABSTRACT FROM AUTHOR]

Published

2023

22. Spectral Aerosol Radiative Forcing and Efficiency of the La Palma Volcanic Plume over the Izaña Observatory.

Author

García, Rosa Delia, García, Omaira Elena, Cuevas-Agulló, Emilio, Barreto, África, Cachorro, Victoria Eugenia, Marrero, Carlos, Almansa, Fernando, Ramos, Ramón, and Pó, Mario

Subjects

*RADIATIVE forcing, *VOLCANIC plumes, *AEROSOLS, *VOLCANIC ash, tuff, etc., *OBSERVATORIES, *MINERAL dusts, *DUST

Abstract

On 19 September 2021, a volcanic eruption began on the island of La Palma (Canary Islands, Spain). The eruption has allowed the assessment of an unprecedented multidisciplinary study on the effects of the volcanic plume. This work presents the estimation of the spectral direct radiative forcing (Δ F) and efficiency (Δ F E f f ) from solar radiation measurements at the Izaña Observatory (IZO) located on the island of Tenerife (∼140 km from the volcano). During the eruption, the IZO was affected by different types of aerosols: volcanic, Saharan mineral dust, and a mixture of volcanic and dust aerosols. Three case studies were identified using ground-based (lidar) data, satellite-based (Sentinel-5P Tropospheric Monitoring Instrument, TROPOMI) data, reanalysis data (Modern-Era Retrospective Analysis for Research and Applications, version 2, MERRA-2), and backward trajectories (Flexible Trajectories, FLEXTRA), and subsequently characterised in terms of optical and micro-physical properties using ground-based sun-photometry measurements. Despite the Δ F of the volcanic aerosols being greater than that of the dust events (associated with the larger aerosol load present), the Δ F E f f was found to be lower. The spectral Δ F E f f values at 440 nm ranged between −1.9 and −2.6 Wm − 2 nm − 1 AOD − 1 for the mineral dust and mixed volcanic and dust particles, and between −1.6 and −3.3 Wm − 2 nm − 1 AOD − 1 for the volcanic aerosols, considering solar zenith angles between 30 ∘ and 70 ∘ , respectively. [ABSTRACT FROM AUTHOR]

Published

2023

23. Influence of Technical Parameters of the Pyrolysis Process on the Surface Area, Porosity, and Hydrophobicity of Biochar from Sunflower Husk Pellet.

Author

Wystalska, Katarzyna, Kwarciak-Kozłowska, Anna, and Włodarczyk, Renata

Abstract

Biochar is a product that has been of interest to many researchers in recent years. The use and positive effect of biochar depend on its properties, which in turn result primarily from the type of substrate used for production and the technical parameters of the pyrolysis process used. From the point of view of sustainable development, agricultural raw materials, such as sunflower husks, are good materials for biochar synthesis. The research aimed to determine the effect of changing the technical parameters of the pyrolysis process (i.e., temperature, heating rate, and residence time) on the properties of biochar obtained from sunflower husk pellets. The pellets were heated to 480 °C, 530 °C, and 580 °C. The applied heating rate for 480 °C was 4.00 and 7.38 °C·min−1, for 530 °C it was 4.42 and 8.15 °C·min−1 and for 580 °C it was 4.83 and 8.92 °C·min−1. Determining these properties is important due to the use of biochar, e.g., in the processes of sorption of pollutants from the water and soil environment. The technical parameters of the pyrolysis process used allowed us to obtain hydrophilic materials with porosity in the range of 10.11% to 15.43% and a specific surface area of 0.93 m2·g−1 to 2.91 m2·g−1. The hydrophilic nature of biochar makes it possible to use them in the processes of removing inorganic pollutants and polar organic pollutants. The presence of macropores in biochar may contribute to the improvement of water management in the soil and affect the assimilation of microelements by plants. The low content of heavy metals in biochar does not pose a threat to the environment. [ABSTRACT FROM AUTHOR]

Published

2023

24. Effects of Heating Rate and Temperature on the Thermal Pyrolysis of Expanded Polystyrene Post-Industrial Waste.

Author

Gonzalez-Aguilar, Arantxa M., Cabrera-Madera, Victoria P., Vera-Rozo, James R., and Riesco-Ávila, José M.

Subjects

*POLYSTYRENE, *PYROLYSIS, *WASTE minimization, *PLASTICS, *FACTOR analysis, *PETROLEUM chemicals industry, *CHEMICAL industry, *MICROBIAL exopolysaccharides, *PLASTIC scrap

Abstract

The use of plastic as material in various applications has been essential in the evolution of the technology industry and human society since 1950. Therefore, their production and waste generation are high due to population growth. Pyrolysis is an effective recycling method for treating plastic waste because it can recover valuable products for the chemical and petrochemical industry. This work addresses the thermal pyrolysis of expanded polystyrene (EPS) post-industrial waste in a semi-batch reactor. The influence of reaction temperature (350–500 °C) and heating rate (4–40 °C min−1) on the liquid conversion yields and physicochemical properties was studied based on a multilevel factorial statistical analysis. In addition, the analysis of the obtaining of mono-aromatics such as styrene, toluene, benzene, ethylbenzene, and α-methyl styrene was performed. Hydrocarbon liquid yields of 76.5–93% were achieved at reaction temperatures between 350 and 450 °C, respectively. Styrene yields reached up to 72% at 450 °C and a heating rate of 25 °C min−1. Finally, the potential application of the products obtained is discussed by proposing the minimization of EPS waste via pyrolysis. [ABSTRACT FROM AUTHOR]

Published

2022

25. Reference Test Method for Calculating the Thermal Effect of Coal Spontaneous Combustion.

Author

Liu, Wenyong, Zhang, Wenzhao, Ma, Shuai, and Zhang, Ze

Subjects

*SPONTANEOUS combustion, *COAL combustion, *THERMAL coal, *TEST methods, *CHEMICAL bonds

Abstract

During a heating experiment, there are two sources of heat that increase the temperature of a coal sample: the heat released by the oxidation reaction of the coal itself, and the heat provided by the experimental system. Here, we propose a method for measuring the thermal effect of oxidation and self-ignition through a reference experiment conducted with a material that is physically similar to coal but does not combust. The reference material used was an aggregate of alumina, fly ash, and concrete, and experiments were conducted on both materials simultaneously. The temperature of the coal sample was obtained under self-heating conditions, and compared with that of the non-combusting material. The relationship of temperature as a function of time for both materials was determined from the data, the comparison of which allowed for the thermal effect of oxidation and coal spontaneous combustion (CSC) to be calculated. The reliability of the thermal effect data obtained by the experiment was verified by chemical bond energy estimation. These results provide theoretical guidance for on-site fire prevention and extinguishing in coal mines, and are important for the further development of the understanding of CSC. [ABSTRACT FROM AUTHOR]

Published

2022

26. Heating Rate Effect on Gas Permeability and Pore Structure of Mortar under High Temperature.

Author

Chen, Wei, Liu, Yuehan, Sheng, Mingquan, Zhang, Hejun, Liang, Yue, and Skoczylas, Frederic

Subjects

*POROSITY, *PERMEABILITY, *HIGH temperatures, *SCANNING electron microscopy, *FRACTAL dimensions, *MORTAR, *MICROCRACKS

Abstract

This experimental study investigated the effect of heating rate on mortar gas permeability and microstructure. The mortar was heated to three target temperatures (400 °C, 500 °C, and 600 °C) at three heating rates (5 °C/min,10 °C/min, and 15 °C/min). The variations of gas permeability and porosity were measured simultaneously at different confining pressures, and the changes in mortar microstructure were analyzed by NMR and SEM techniques. The results show that the porosity and gas permeability increase with an increase in temperature and heating rate. The gas permeability and porosity continue to decrease as confinement is increased due to a reduction in the pore volume. The microstructure observed by SEM indicates that the high heating rate induces some microcracks at 500 °C and 600 °C. The fractal dimension based on NMR can quantitatively characterize the complexity of the mortar pore structure and shows a quadratic decreasing relationship with gas permeability and porosity. [ABSTRACT FROM AUTHOR]

Published

2022

27. A Study on the Structural Features of Amorphous Nanoparticles of Ni by Molecular Dynamics Simulation.

Author

Tran Quoc, Tuan, Nguyen Trong, Dung, Cao Long, Van, Saraç, Umut, and Ţălu, Ştefan

Subjects

MOLECULAR dynamics, GLASS transition temperature, NANOPARTICLES

Abstract

This study deals with the impact of the heating rate (HR), temperature (T), and the number of atoms (N) on the structural features of amorphous nanoparticles (ANPs) of Ni by molecular dynamics simulation (MDS) with the Pak–Doyama pair interaction potential field (PD). The obtained results showed that the structural features of ANPs of Ni are significantly affected by the studied factors. The correlation between the size (D) and the N was determined to be D~N−1/3. The energy (E) was proportional to N−1, and the Ni-Ni link length was 2.55 Å. The glass transition temperature (Tg) derived from the E-T graph was estimated to be 630 K. An increase in the HR induced a change in the shape of the ANPs of Ni. Furthermore, raising the HR caused an enhancement in the D and a decrement in the density of atoms. The obtained results are expected to contribute to future empirical studies. [ABSTRACT FROM AUTHOR]

Published

2022

28. Development of Desirable Fine Ferrite Grain Size and Random Second Phase Dual-Phase Steel Microstructures Using Composition and/or Processing Modifications.

Author

Bandi, Bharath, Slater, Carl, Farrugia, Didier, and Davis, Claire

Subjects

DUAL-phase steel, MICROSTRUCTURE, HOT rolling, COLD rolling, PARTICLE size distribution, ROLLING friction

Abstract

Microstructural morphology is known to have a significant impact on the mechanical properties of dual-phase steels. A fine ferrite grain size and random distribution of small second phase islands are desirable to provide superior isotropic properties compared to the banded second phase distribution that is typical for this type of steel. A rapid alloy prototyping (RAP) facility has been used to investigate three different DP 800 variants by systematically varying the compositions and/or process parameters compared to the 'standard' DP800 composition and processing that gives a banded microstructure. For Variant 1, the heating rate during the annealing cycle after cold rolling varied between 0.65 and 30 °C/s for the 45%, 60% and 75% cold reduction samples. It was found that a cold reduction of 75% and heating rate of 15 °C/s resulted in the microstructure that can give the best combination of strength and ductility because of the fine grain size and high martensite volume fraction. For Variant 2, the effect of changing the hot rolled (HR) microstructure (ferrite–pearlite, ferrite–bainite or martensite) on the final microstructure was investigated. Both the ferrite–50% bainite and fully martensite/bainite HR materials for all cold reductions resulted in annealed microstructures with necklace martensite morphology and finer ferrite grains compared to the ferrite–pearlite HR material, which gave a typical banded ferrite–martensite microstructure with a coarser ferrite grain size. For Variant 3, the Mn content was reduced, and increased Nb was used to achieve higher pancaking during the hot rolling stage, which refined ferrite grains in the HR condition with the same hardness. After annealing with the standard parameters only the 45% cold-reduced material produced a finer ferrite grain size than the standard material, whereas the 60% and 75% cold-reduced samples required a higher heating rate to achieve finer ferrite grain sizes due to rapid recrystallisation and growth kinetics. [ABSTRACT FROM AUTHOR]

Published

2022

29. The Effect of the Heating Rate during Carbonization on the Porosity, Strength, and Electrical Resistivity of Graphite Blocks Using Phenolic Resin as a Binder.

Author

Lee, Sang-Hye, Kim, Jae-Hyun, Kim, Woo-Seok, and Roh, Jae-Seung

Subjects

*PHENOLIC resins, *ELECTRICAL resistivity, *GRAPHITE, *CARBONIZATION, *POROSITY, *FLEXURAL strength

Abstract

In the present study, graphite blocks were fabricated using synthetic graphite scrap and phenolic resin, and the effect of the heating rate during carbonization on their mechanical and electrical characteristics was examined. While varying the heating rate from 1, 3, 5, and 7 to 9 °C/min, the microstructure, density, porosity, flexural strength, compressive strength, and electrical resistivity of the fabricated graphite blocks were measured. As the heating rate increased, the pores in the graphite blocks increased in size, and the shape of the gas release paths became more irregular. Overall, it was found that increases in the heating rate led to the degradation of the graphite blocks' mechanical and electrical properties. [ABSTRACT FROM AUTHOR]

Published

2022

30. Pitfalls of Using Biomarker Maturity Parameters for Organic Matter Maturity Assessment Suggested by Coal Hydrous Pyrolysis.

Author

Yin, Mengsha and Huang, Haiping

Subjects

*COAL pyrolysis, *ORGANIC compounds, *COAL combustion, *BIOMARKERS, *GEOCHEMISTRY, *ISOMERS, *PETROLEUM, *PETROLEUM products

Abstract

Crude oil maturity assessment is a vital goal for petroleum geochemistry, and equally important is the exploration of maturity indicators of sufficient credibility. While most molecular proxy parameters have been extensively used and have provided some useful insights; the component ratios approach is somewhat limited in validity regarding oil maturity characterization for variable reasons. Novel thermal trends of hopanes and steranes were observed in a series of hydrous pyrolysates of an immature coal (0.49 %Ro) generated at eight target temperatures ranging from 250–375 °C (measured vitrinite reflectance of 0.71–0.91 %Rm), which–further substantiated this idea. Expelled oil and extractable bitumen were combined as the total soluble organic material (tSOM) for each pyrolysis experiment to mitigate the effects of primary expulsion fractionation. While bitumen extracted from the original coal—the 250 °C tSOM—the 275 °C tSOM (0.49–0.73 %Rm) sequence recorded normal increases in C31 αβ-hopane 22S/(22S + 22R) and decreases in C29–C30 βα-moretane/αβ-hopane ratios, low values and continuous decreases in C29 5α-sterane 20S/(20S + 20R) and ββ/(αα + ββ), Ts/(Ts + Tm) and C29Ts/(C29Ts + C29 αβ-hopane) suggested no biomarker thermal isomerization but predominant control from precursor-to-biomarker transformation. Continuous increases in 22S/(22S + 22R) until 1.43 %Rm accorded with thermal isomerization, but a delayed ratio equilibration at 1.43 %Rm again suggested biomarker precursor interference, which also played a role in the reductions in 20S/(20S + 20R) and ββ/(αα + ββ) to 0.9 %Rm, whereas increasing and high values of C29–C30 βα-moretane/αβ-hopane ratios occurring during 0.73–1.43 %Rm. Reversals in 22S/(22S + 22R) and fluctuations in 20S/(20S + 20R) and ββ/(αα + ββ) at elevated maturity levels with minimum yields of biomarker precursors were predominantly controlled by differential isomer degradative rates. These rarely reported thermal distribution patterns of biomarkers illustrated very complicated biomarker generation–destruction processes during maturation and suggested that the release of bond biomarker to the free status may govern the biomarker maturity ratios rather than thermal isomerization. While the rapid heating conditions and high temperatures in pyrolysis differ inevitably from natural evolution under geological conditions, our study unveiled that unusual biomarker ratios in geological samples could be the norm, contradictory to common beliefs. Accordingly, we propose that isomer concentration is an essential tool to validate maturity estimation of organic matter by isomer ratios, especially for highly mature oils and sediment extracts. [ABSTRACT FROM AUTHOR]

Published

2022

31. Influence of Natural Fire Development on Concrete Compressive Strength.

Author

Kuehnen, Robert, Youssef, Maged A., and El-Fitiany, Salah F.

Subjects

*COMPRESSIVE strength, *FIRE exposure, *CONCRETE, *CONCRETE testing, *HIGH temperatures, *EFFECT of temperature on concrete

Abstract

With increasing acceptance of performance-based design principles in the field of fire safety, it is imperative to accurately define the behaviour of materials during fire exposure. Real-world fire events, otherwise referred to as natural fires, are defined by four characteristics: heating rate, maximum temperature, exposure duration, and cooling rate. Each of these four characteristics influences concrete's behaviour in a different manner. In this paper, the available experimental work for concrete, tested at elevated temperatures, is examined to identify the influence of the four natural fire characteristics on concrete compressive strength. This review focuses on normal strength concrete tests only, omitting parameters such as unique additives and confinement. The intent is to provide a fundamental understanding of normal strength concrete. The findings show that maximum temperature and cooling rates have a significant influence on concrete strength. Exposure duration has a moderate impact, particularly at shorter durations. Variable rates of heating have minimal influence on strength. Detailed conclusions are provided along with review limitations, practical considerations for designers, and future research needs. [ABSTRACT FROM AUTHOR]

Published

2022

32. A Multi-Physic Modelling Insight into the Differences between Microwave and Conventional Heating for the Synthesis of TiO 2 Nanoparticles.

Author

Poppi, Giulia, Colombini, Elena, Salvatori, Diego, Balestri, Alessio, Baldi, Giovanni, Leonelli, Cristina, and Veronesi, Paolo

Subjects

MICROWAVE heating, TITANIUM dioxide, TEMPERATURE distribution, TITANIUM oxides, NANOPARTICLES, MICROWAVE sintering

Abstract

Microwave-assisted synthesis of nanoparticles usually leads to a smaller and more uniformly distributed particle size compared to conventional heating (e.g., oil bath). Numerical simulation can help to obtain a better insight into the process in terms of temperature distribution or to evidence existing different temperature profiles and heating rates between the two techniques. In this paper multi-physics numerical simulation is used to investigate the continuous flow synthesis of titanium oxide nanoparticles starting from alkoxide precursors. Temperature-dependent permittivity of reactants has been measured, including the effects of permanence at the maximum synthesis temperature. A temperature homogeneity index has been defined to compare microwave and conventional heating. Results show that when using microwave heating at 2450 MHz, in the investigated conditions, a much higher temperature homogeneity of the reactants is reached. Moreover, reactants experience different heating rates, depending on their position inside the microwave applicator, while this is almost negligible in the case of conventional heating. [ABSTRACT FROM AUTHOR]

Published

2022

33. Characteristics Analysis of Fluid Flow and Heating Rate of a Molten Bath Utilizing a Unified Model in a DC EAF.

Author

Yao, Conglin, Jiang, Zhouhua, Zhu, Hongchun, and Pan, Tao

Subjects

FLUID flow, ELECTRIC arc, PLASMA arcs, ARC furnaces, ELECTRIC furnaces, FREE surfaces, JET impingement

Abstract

Herein, a 2D unified model coupling a plasma arc–molten bath–cavity in a direct current electric arc furnace was developed for a characteristic analysis of the fluid flow and heating rate of the molten bath. The 'local thermodynamic equilibrium–diffusion approximation' method was employed for the physical phenomenon at the plasma arc/molten bath interface, and the volume-of-fluid method was used to track the free surface. After ensuring model validation, the formation processes of the cavity and the flow field and heating rate of the molten bath were investigated by utilizing the unified model. The numerical results showed that the formation processes of the cavity contained three stages, namely the expansion, compression, and dynamic equilibrium stages. The arc pressure and plasma shear stress both contributed to the cavity formation, and dominated the expansion of the cavity depth and diameter, respectively. Under plasma arc jet impingement, there were two flow patterns inside the molten bath: (i) a clockwise eddy on the top surface and lateral part of molten bath dominated by plasma shear stress, and (ii) a counter-clockwise eddy in the bottom part of the molten bath dominated by the electromagnetic force. Meanwhile, the main heated region of the molten bath with the plasma arc–molten bath–cavity coupling was in the radial range of 0.2–0.6 m, and a high-temperature region was formed on the top surface of the molten bath caused by plasma shear stress. [ABSTRACT FROM AUTHOR]

Published

2022

34. Experimental Investigations on Temperature Generation and Release of Ultra-High Performance Concrete during Fatigue Tests.

Author

Deutscher, Melchior, Tran, Ngoc Linh, and Scheerer, Silke

Subjects

CONCRETE fatigue, MATERIAL fatigue, REINFORCED concrete construction, THERMAL conductivity, EFFECT of temperature on concrete, TEMPERATURE

Abstract

Smarter, more filigree, and resource-saving buildings are the aim of developments in the construction industry. In reinforced concrete construction, ultra-high strength concretes have been developed to achieve these goals. Due to their use and requirements, these highly pressure-resistant materials are increasingly exposed to cyclically occurring and high-frequency loads. Examples of this are applications in long-span bridges or wind turbines. Research into the fatigue behaviour of the new construction material is therefore very important for the standardization and practical introduction of the high performance material. In this article, we want to investigate the heating process of ultra-high performance concrete (UHPC) under fatigue stress in more detail. In previous investigations in this project, an influence of the heating on the fatigue strength could be determined. A systematic parameter study has defined decisive load configurations for a maximum heating process. The aim is now to better understand the heating process. For this purpose, the temperature generation rate and the temperature release, which probably influences the overall temperature development, are investigated. A test program with eight experiments gives information about the temperature release during the experiment and the heating rate with and without pre-damage in the sample. In addition, the causes of failure caused by temperature are investigated with additional insulated tests. The results are presented, discussed, and conclusions are drawn in the article. For instance, fatigue damage affects the rate of temperature increase, but not the thermal conductivity of the material. In the different configurations, the test specimens essentially overlap at the maximum temperature reached in the inner test specimen. In addition to the assumed influence of the temperature gradients in the cross section as a cause of premature failure due to additional constraint stresses, the maximum temperature in particular turns out to be decisive, independent of the gradient. [ABSTRACT FROM AUTHOR]

Published

2020

35. Investigation and Modeling of the Preheating Effects on Precipitation and Hot Flow Behavior for Forming High Strength AA7075 at Elevated Temperatures.

Author

Kailun Zheng, Yong Li, Song Yang, Kunning Fu, Jinghua Zheng, Zhubin He, and Shijian Yuan

Subjects

ALUMINUM alloys, PRECIPITATION (Chemistry), HIGH temperatures, TRANSMISSION electron microscopy, CRITICAL temperature

Abstract

Preheating is the first but critical step for hot stamping high strength precipitate hardened aluminum alloys. To thoroughly understand the effects of preheating conditions--i.e., preheating rate and heating temperature--on the strength and hot deformation of aluminum alloys, a series of thermal--mechanical tests was performed to determine the post-hardness evolution and hot flow behaviors. Typical microstructures with different preheating conditions were also observed through transmission electron microscopy (TEM), with which a unified model of both hot flow and strength based on key microstructural variables was developed, enabling the successful prediction of macroscopic properties using different preheating strategies. The results have shown that for high strength AA7075 at the T6 condition, the dominant mechanism of precipitate evolution with increasing temperature is the coarsening of precipitates first, followed by dissolution when they exceed a critical temperature. A higher heating rate results in a slower coarsening and a relatively higher strength level. In addition, the flow stress of hot deformation is also higher using a quick heating rate, with more significant softening and reduced ductility. [ABSTRACT FROM AUTHOR]

Published

2020

36. Anthropic Settlements’ Impact on the Light-Absorbing Aerosol Concentrations and Heating Rate in the Arctic

Author

Losi, N, Markuszewski, P, Rigler, M, Gregorič, A, Močnik, G, Drozdowska, V, Makuch, P, Zielinski, T, Pakszys, P, Kitowska, M, Cefalì, A, Gini, I, Doldi, A, Cerri, S, Maroni, P, Bolzacchini, E, Ferrero, L, Losi N., Markuszewski P., Rigler M., Gregorič A., Močnik G., Drozdowska V., Makuch P., Zielinski T., Pakszys P., Kitowska M., Cefalì A. M., Gini I., Doldi A., Cerri S., Maroni P., Bolzacchini E., Ferrero L., Losi, N, Markuszewski, P, Rigler, M, Gregorič, A, Močnik, G, Drozdowska, V, Makuch, P, Zielinski, T, Pakszys, P, Kitowska, M, Cefalì, A, Gini, I, Doldi, A, Cerri, S, Maroni, P, Bolzacchini, E, Ferrero, L, Losi N., Markuszewski P., Rigler M., Gregorič A., Močnik G., Drozdowska V., Makuch P., Zielinski T., Pakszys P., Kitowska M., Cefalì A. M., Gini I., Doldi A., Cerri S., Maroni P., Bolzacchini E., and Ferrero L.

Abstract

Light-absorbing aerosols (LAA) impact the atmosphere by heating it. Their effect in the Arctic was investigated during two summer Arctic oceanographic campaigns (2018 and 2019) around the Svalbard Archipelago in order to unravel the differences between the Arctic background and the local anthropic settlements. Therefore, the LAA heating rate (HR) was experimentally determined. Both the chemical composition and high-resolution measurements highlighted substantial differences between the Arctic Ocean background (average eBC concentration of 11.7 ± 0.1 ng/m3) and the human settlements, among which the most impacting appeared to be Tromsø and Isfjorden (mean eBC of 99.4 ± 3.1 ng/m3). Consequently, the HR in Isfjorden (8.2 × 10−3 ± 0.3 × 10−3 K/day) was one order of magnitude higher than in the pristine background conditions (0.8 × 10−3 ± 0.9 × 10−5 K/day). Therefore, we conclude that the direct climate impact of local LAA sources on the Arctic atmosphere is not negligible and may rise in the future due to ice retreat and enhanced marine traffic.

Published

2023

37. Experimental Investigations on the Temperature Increase of Ultra-High Performance Concrete under Fatigue Loading.

Author

Deutscher, Melchior, Tran, Ngoc Linh, and Scheerer, Silke

Subjects

CONCRETE fatigue, HIGH strength concrete, REINFORCED concrete construction, DEAD loads (Mechanics), CONSTRUCTION materials, EFFECT of temperature on concrete

Abstract

Leaner, more filigree, and resource-saving constructions are the development goal of the in the building industry. In reinforced concrete construction, a ultra-high strength concrete was developed to achieve these goals. Due to its use and requirements, this very pressure-resistant material is no longer only exposed to static loads. In applications such as wide-span bridges, machine foundations and wind turbines, the susceptibility to vibration is also significant. Research into the fatigue behavior of the new building material is therefore very important. In this article we will discuss the effect of heating up of high performance concretes under fatigue stress. The thesis is that warming up, which was already observed by several research groups, has an influence on the fatigue strength. Changes in the strength of the concrete or residual stresses generated by heating can lead to early failure. The aim is to find the reasons for the heating and the grade of influence on the fatigue strength. A systematic test program was developed to investigate the influencing parameters maximum stress level, frequency, and maximum grain size of the concrete. Thirty fatigue tests were carried out; the results will be presented here. The influence on the temperature increase as well as on the heating rate for the individual parameters will be discussed. The results show that all three discussed parameters have a significant influence on the temperature rise. Whereas the maximum temperature reached depends strongly on the frequency, the other two parameters mainly influence the heating rate. [ABSTRACT FROM AUTHOR]

Published

2019

38. Spectral aerosol radiative forcing and efficiency of the La Palma volcanic plume over the Izaña Observatory

Author

García Cabrera, Rosa Delia, García Rodríguez, Omaira Elena, Cuevas Agulló, Emilio, Barreto Velasco, África, Cachorro, Victoria E., Marrero, Carlos, Almansa Rodríguez, Antonio Fernando, Ramos López, Ramón, and Pó, Mario

Subjects

Saharan mineral dust, Spectral radiative forcing efficiency, Spectral radiative forcing, Heating rate, volcanic aerosols, La Palma volcano

Abstract

On 19 September 2021, a volcanic eruption began on the island of La Palma (Canary Islands, Spain). The eruption has allowed the assessment of an unprecedented multidisciplinary study on the effects of the volcanic plume. This work presents the estimation of the spectral direct radiative forcing (∆F) and efficiency (∆F E f f) from solar radiation measurements at the Izaña Observatory (IZO) located on the island of Tenerife (∼140 km from the volcano). During the eruption, the IZO was affected by different types of aerosols: volcanic, Saharan mineral dust, and a mixture of volcanic and dust aerosols. Three case studies were identified using ground based (lidar) data, satellite-based (Sentinel5P Tropospheric Monitoring Instrument, TROPOMI) data, reanalysis data (Modern-Era Retrospective Analysis for Research and Applications, version 2, MERRA-2), and backward trajectories (Flexible Trajectories, FLEXTRA), and subsequently characterised in terms of optical and micro-physical properties using ground based sun-photometry measurements. Despite the ∆F of the volcanic aerosols being greater than that of the dust events (associated with the larger aerosol load present), the ∆F E f f was found to be lower. The spectral ∆F E f f values at 440 nm ranged between −1.9 and −2.6 Wm−2nm−1AOD−1 for the mineral dust and mixed volcanic and dust particles, and between −1.6 and −3.3 Wm−2nm−1AOD−1 for the volcanic aerosols, considering solar zenith angles between 30◦ and 70◦, respectively. The authors also acknowledge the support of ACTRIS, Ministerio de Ciencia e Innovación of Spain, through the projects SYNERA: PID2020-118793GA-I00 and RT2018- 097864-B-I00, and Junta de Castilla y León grant N◦. VA227P20.

Published

2023

39. Heat Transfer Limitations in Supercritical Water Gasification

Author

Universidad de Sevilla. Departamento de Ingeniería Química y Ambiental, Universidad de Sevilla. Departamento de Ingeniería Energética, Universidad de Sevilla.TEP137: Maquinas y Motores Termicos, Consejeria de Economia y Conocimiento (Junta de Andalucia) P18-RT-2521, Gutiérrez Ortiz, Francisco Javier, López-Guirao, Francisco, Jiménez-Espadafor Aguilar, Francisco José, Benjumea Trigueros, José Manuel, Universidad de Sevilla. Departamento de Ingeniería Química y Ambiental, Universidad de Sevilla. Departamento de Ingeniería Energética, Universidad de Sevilla.TEP137: Maquinas y Motores Termicos, Consejeria de Economia y Conocimiento (Junta de Andalucia) P18-RT-2521, Gutiérrez Ortiz, Francisco Javier, López-Guirao, Francisco, Jiménez-Espadafor Aguilar, Francisco José, and Benjumea Trigueros, José Manuel

Abstract

Supercritical water gasification (SCWG) is a promising technology for the valorization of wet biomass with a high-water content, which has attracted increasing interest. Many experimental studies have been carried out using conventional heating equipment at lab scale, where researchers try to obtain insight into the process. However, heat transfer from the energy source to the fluid stream entering the reactor may be ineffective, so slow heating occurs that produces a series of undesirable reactions, especially char formation and tar formation. This paper reviews the limitations due to different factors affecting heat transfer, such as low Reynolds numbers or laminar flow regimes, unknown real fluid temperature as this is usually measured on the tubing surface, the strong change in physical properties of water from subcritical to supercritical that boosts a deterioration in heat transfer, and the insufficient mixing, among others. In addition, some troubleshooting and new perspectives in the design of efficient and effective devices are described and proposed to enhance heat transfer, which is an essential aspect in the experimental studies of SCWG to move it forward to a larger scale.

Published

2022

40. Effect of Heating Rate on Pyrolysis Behavior and Kinetic Characteristics of Siderite.

Author

Xiaolong Zhang, Yuexin Han, Yanjun Li, and Yongsheng Sun

Subjects

*SIDERITE, *PYROLYSIS, *IRON ores, *MAGNETOMETERS, *CHEMICAL reactions, *SCANNING electron microscopes, *ENERGY dispersive X-ray spectroscopy

Abstract

The pyrolysis characteristics of siderite at different heating rates under the neutral atmosphere were investigated using various tools, including comprehensive thermal analyzer, tube furnace, X-ray diffraction (XRD), scanning electron microscope (SEM), energy-dispersive spectrometry (EDS) and vibrating specimen magnetometer (VSM) measurements. The reaction of siderite pyrolysis followed the one-step reaction under the neutral atmosphere: FeCO3→Fe3O4 + CO2 + CO. As the increasing of heating rate, the start and end pyrolysis temperatures and temperate where maximum weight loss rate occurred increased, while the total mass loss were essentially the same. Increasing heating rate within a certain range was in favor of shortening the time of each reaction stage, and the maximum conversion rate could be reached with a short time. The most probable mechanism function for non-isothermal pyrolysis of siderite at different heating rates was A1/2 reaction model (nucleation and growth reaction). With increasing heating rate, the corresponding activation energies and the pre-exponential factors increased, from 446.13 to 505.19 kJ.mol-1, and from 6.67 × 10-18 to 2.40 × 10-21, respectively. All siderite was transformed into magnetite with a porous structure after pyrolysis, and some micro-cracks were formed into the particles. The magnetization intensity and specific susceptibility increased significantly, which created favorable conditions for the further effective concentration of iron ore. [ABSTRACT FROM AUTHOR]

Published

2017

41. Influence of the Heating Rate on the Foaming Behavior of Various Aluminium Alloys.

Author

Neu, Tillmann R., Pfretzschner, Beate, García-Moreno, Francisco, and Banhart, John

Subjects

ALUMINUM alloys, METAL foams, HEATING of metals, POWDER metallurgy, EFFECT of temperature on metals

Abstract

Powders of metallurgically prepared precursors expand to a foam differently depending on how fast they are heated to their foaming temperature. The foaming behavior of four alloys was studied with heating rates varying from 0.1 K/s to 18 K/s. It was found that each alloy shows its own non-linear behavior of expansion values. Alloys not containing magnesium exhibit a maximum at intermediate heating rates, whereas Mg-containing alloys tend to expand more for higher heating rates. [ABSTRACT FROM AUTHOR]

Published

2017

42. Heat Transfer Limitations in Supercritical Water Gasification

Author

Gutiérrez Ortiz, Francisco Javier, López-Guirao, Francisco, Jiménez-Espadafor Aguilar, Francisco José, Benjumea Trigueros, José Manuel, Universidad de Sevilla. Departamento de Ingeniería Química y Ambiental, Universidad de Sevilla. Departamento de Ingeniería Energética, Universidad de Sevilla.TEP137: Maquinas y Motores Termicos, and Consejeria de Economia y Conocimiento (Junta de Andalucia) P18-RT-2521

Subjects

Heat transfer, Reforming, Heating rate, Tubular reactor, Gasification, Supercritical water

Abstract

Supercritical water gasification (SCWG) is a promising technology for the valorization of wet biomass with a high-water content, which has attracted increasing interest. Many experimental studies have been carried out using conventional heating equipment at lab scale, where researchers try to obtain insight into the process. However, heat transfer from the energy source to the fluid stream entering the reactor may be ineffective, so slow heating occurs that produces a series of undesirable reactions, especially char formation and tar formation. This paper reviews the limitations due to different factors affecting heat transfer, such as low Reynolds numbers or laminar flow regimes, unknown real fluid temperature as this is usually measured on the tubing surface, the strong change in physical properties of water from subcritical to supercritical that boosts a deterioration in heat transfer, and the insufficient mixing, among others. In addition, some troubleshooting and new perspectives in the design of efficient and effective devices are described and proposed to enhance heat transfer, which is an essential aspect in the experimental studies of SCWG to move it forward to a larger scale. Consejeria de Economia y Conocimiento (Junta de Andalucia) P18-RT-2521

Published

2022

43. Effects of prior microstructure and heating rate on the depth of increased hardness in laser hardening

Author

Mole, Nikolaj, Bojinović, Marko, Koc, Pino, and Štok, Boris

Subjects

mikrostrukture, heating rate, prior microstructures, computer simulations, računalniške simulacije, udc:539.4(045), hitrost segrevanja, lasersko kaljenje, laser hardening

Abstract

The response of the hypo-eutectoid steel to laser hardening, which is measured as the depth of the increased hardness, depends not only on the set of the process parameters but also on the prior microstructure of the workpiece. The multiple preliminary stages of the treatment of the workpiece in the industrial conditions are commonly not completely known, resulting in an unclear prior microstructure of the workpiece. To model the response of the hypo-eutectoid steel, a validated numerical model for laser hardening has been used in the computer simulation of the process for four different cases. The numerical model takes into account the 3D geometry of the workpiece, its prior microstructure, and the effect of the heating rate during the laser hardening process on the kinetics of the phase transformation. The four cases were designed to take into account two different sets of process parameters and two different prior microstructures of the workpiece. The output of the computer simulation was verified experimentally.

Published

2021

44. Explosive Spalling Behavior of Single-Sided Heated Concrete According to Compressive Strength and Heating Rate

Author

Minjae Son, Dongkyun Suh, Gyeongcheol Choe, Jeongsoo Nam, Ha-Min Eu, Min-Ho Yoon, Gyu-Yong Kim, and Eui-Chul Hwang

Subjects

Technology, Materials science, Explosive material, restrained stress, Vapor pressure, heating rate, explosive spalling, Article, ring-restrained concrete, Clogging, Stress (mechanics), Ultimate tensile strength, General Materials Science, Composite material, Microscopy, QC120-168.85, vapor pressure, Moisture, QH201-278.5, single-sided heat, Engineering (General). Civil engineering (General), Spall, compressive strength, TK1-9971, Compressive strength, Descriptive and experimental mechanics, Electrical engineering. Electronics. Nuclear engineering, TA1-2040

Abstract

In this study, the effects of heating rate and compressive strength on the spalling behavior of single-sided heated ring-restrained concrete with compressive strengths of 60 and 100 MPa were investigated. The vapor pressure and restrained stress inside the concrete were evaluated under fast- and slow-heating conditions. Regardless of the heating rate, the concrete vapor pressure and restrained stress increased as the temperature increased, and it was confirmed that spalling occurred in the 100-MPa concrete. Specifically, it was found that moisture migration and restrained stress inside the concrete varied depending on the heating rate. Under fast heating, moisture clogging and restrained stress occurred across the concrete surface, causing continuous surface spalling for the 100-MPa concrete. Under slow heating, moisture clogging occurred, and restrained stress continuously increased in the deep area of the concrete cross-section owing to the small internal temperature difference, resulting in explosive spalling for the 100-MPa concrete with a dense internal structure. Additionally, while the tensile strength of concrete is reduced by heating, stress in the heated surface direction is generated by restrained stress. The combination of stress in the heated concrete surface and the internal vapor pressure generates spalling. The experimental results confirm that heating rate has a significant influence on moisture migration and restrained stress occurrence inside concrete, which are important factors that determine the type of spalling.

Published

2021

45. Effect of the Heating Rate to Prevent the Generation of Iron Oxides during the Hydrothermal Synthesis of LiFePO4

Author

J. Sánchez-Oneto, Almudena Benítez, Enrique J. Martínez de la Ossa, M. Belén García-Jarana, J.R. Portela, Francisco Ruiz-Jorge, and Ingeniería Química y Tecnología de Alimentos

Subjects

Materials science, Reducing agent, General Chemical Engineering, Lithium iron phosphate, heating rate, Metallurgy, Electrolyte, Manufacturing cost, Cathode, law.invention, Chemistry, chemistry.chemical_compound, hydrothermal synthesis, chemistry, lithium iron phosphate, law, morphology, crystallinity and purity, Hydrothermal synthesis, General Materials Science, QD1-999, Separator (electricity), Magnetite

Abstract

Lithium-ion batteries (LIBs) have gained much interest in recent years because of the increasing energy demand and the relentless progression of climate change. About 30% of the manufacturing cost for LIBs is spent on cathode materials, and its level of development is lower than the negative electrode, separator diaphragm and electrolyte, therefore becoming the "controlling step". Numerous cathodic materials have been employed, LiFePO4 being the most relevant one mainly because of its excellent performance, as well as its rated capacity (170 mA center dot h center dot g(-1)) and practical operating voltage (3.5 V vs. Li+/Li). Nevertheless, producing micro and nanoparticles with high purity levels, avoiding the formation of iron oxides, and reducing the operating cost are still some of the aspects still to be improved. In this work, we have applied two heating rates (slow and fast) to the same hydrothermal synthesis process with the main objective of obtaining, without any reducing agents, the purest possible LiFePO4 in the shortest time and with the lowest proportion of magnetite impurities. The reagents initially used were: FeSO4, H3PO4, and LiOH, and a crucial phenomenon has been observed in the temperature range between 130 and 150 degrees C, being verified with various techniques such as XRD and SEM., A. Benitez thanks the financial support from the European Social Fund and Junta de Andalucia. Finally, the authors wish to acknowledge the technical staff from the University Institute of Nanochemistry (IUNAN) of the University of Cordoba. This research received no external funding.

Published

2021

46. Surface Structure Engineering of Nanosheet-Assembled NiFe2O4 Fluffy Flowers for Gas Sensing

Author

Xue-Zhi Song, Zi-Hao Wang, Zhenquan Tan, Guo-Zheng Zhang, Xu Li, and Xiaofeng Wang

Subjects

Morphology (linguistics), Materials science, Scanning electron microscope, Annealing (metallurgy), General Chemical Engineering, Communication, heating rate, Crystal structure, gas sensor, lcsh:Chemistry, NiFe2O4, lcsh:QD1-999, X-ray photoelectron spectroscopy, Chemical engineering, Specific surface area, General Materials Science, nanosheet flowers, Bimetallic strip, Nanosheet

Abstract

In this work, we present a strategy to improve the gas-sensing performance of NiFe2O4 via a controllable annealing Ni/Fe precursor to fluffy NiFe2O4 nanosheet flowers. X-ray diffraction (XRD), a scanning electron microscope (SEM), nitrogen adsorption–desorption measurements and X-ray photoelectron spectroscopy (XPS) were used to characterize the crystal structure, morphology, specific surface area and surface structure. The gas-sensing performance was tested and the results demonstrate that the response was strongly influenced by the specific surface area and surface structure. The resultant NiFe2O4 nanosheet flowers with a heating rate of 8 °C min−1, which have a fluffier morphology and more oxygen vacancies in the surface, exhibited enhanced response and shortened response time toward ethanol. The easy approach facilitates the mass production of gas sensors based on bimetallic ferrites with high sensing performance via controlling the morphology and surface structure.

Published

2021

47. Biomass Pyrolysis: Comments on Some Sources of Confusions in the Definitions of Temperatures and Heating Rates.

Author

Lédé, Jacques

Subjects

*BIOMASS, *PYROLYSIS, *POWER resources, *TEMPERATURE, *HEAT transfer, *CHEMICAL reactions, *SURFACE energy, *RENEWABLE energy sources, *THERMAL conductivity

Abstract

Biomass pyrolysis is usually characterized on the basis of temperature and heating rate. Unfortunately, these parameters are badly defined in processing reactors as well as in laboratory devices. From the results of simplified models, the present paper points out the significant mistakes that can be made when assuming that the actual temperature and heating rate of reacting biomass particles are the same as those of the external heating medium. The difficulties in defining these two parameters are underlined in both cases of a heat source temperature supposed to be constant or to increase with time. [ABSTRACT FROM AUTHOR]

Published

2010

48. Effect of Heating Rate on the Photocatalytic Activity of Ag–TiO 2 Nanocomposites by One-Step Process via Aerosol Routes.

Author

Kusdianto, Kusdianto, Hudandini, Meditha, Jiang, Dianping, Kubo, Masaru, and Shimada, Manabu

Subjects

*PLASMA-enhanced chemical vapor deposition, *PHYSICAL vapor deposition, *PHOTOCATALYSTS, *AEROSOLS, *NANOCOMPOSITE materials

Abstract

Ag–TiO2 nanocomposite films, based of Ag and TiO2 nanoparticles, were fabricated in a one-step aerosol route employing the simultaneous plasma-enhanced chemical vapor deposition and physical vapor deposition systems. The as-fabricated films were subjected to different heating rates (3 to 60 °C/min) with a constant annealing temperature of 600 °C to observe the significant changes in the properties (e.g., nanoparticle size, crystalline size, crystallite phase, surface area) toward the photocatalytic performance. The photocatalytic activity was evaluated by the measurement of the degradation of a methylene blue aqueous solution under UV light irradiation, and the results revealed that it gradually increased with the increase in the heating rate, caused by the increased Brunauer–Emmett–Teller (BET) specific surface area and total pore volume. [ABSTRACT FROM AUTHOR]

Published

2022

49. Emigration Effects Induced by Radio Frequency Treatment to Dates Infested by Carpophilus hemipterus

Author

Anita Nencioni, Patrizia Sacchetti, Marzia Cristiana Rosi, Francesco Garbati Pegna, Michele Bicego, Roberto Guidi, and Antonio Belcari

Subjects

0106 biological sciences, Dried fruit, heating rate, physical pest control, Biology, medicine.disease_cause, 01 natural sciences, Article, Toxicology, 03 medical and health sciences, Infestation, medicine, lcsh:Science, 030304 developmental biology, sap beetles, 0303 health sciences, business.industry, Industrial scale, Pest control, 010602 entomology, Carpophilus hemipterus, Physical pest control, Insect Science, lcsh:Q, emigration, PEST analysis, sap beetles, Radio Frequency treatment, emigration, heating rate, physical pest control, business, RF treatment

Abstract

The dried fruit beetle (Carpophilus hemipterus) is considered a key pest of dates, infesting fruits both in the field and during storage. Control measures against the species rely on the use of chemicals or heat treatments based on sunlight, hot air or radio frequency (RF) applications. Previous investigations that have aimed to define control procedures for a total disinfestation using RF treatments with different exposure durations have shown the typical behavior of adults in some trials, which, under the influence of temperature increases, started to escape from infested fruits. We focused on the application of different RF voltage-time combinations to induce the emigration of C. hemipterus adults from dates in order to produce a complete disinfestation. The results showed that the application of 2500 V RF for 8&ndash, 10 min to infested dates resulted in nearly 100% of adults escaping from fruits, thereby cleaning the commodity with low or no mortality inside and outside the dates. These achievements provide a new strategy for controlling key insect pests of dates that could be applied at an industrial scale, allowing for the quick disinfestation of fruits without affecting the fruit with harmful substances, such as residues from chemical treatments, and without unwanted side effects on date quality.

Published

2019

50. Explosive Spalling Behavior of Single-Sided Heated Concrete According to Compressive Strength and Heating Rate.

Author

Hwang, Euichul, Kim, Gyuyong, Choe, Gyeongcheol, Yoon, Minho, Son, Minjae, Suh, Dongkyun, Eu, Hamin, and Nam, Jeongsoo

Subjects

*COMPRESSIVE strength, *CONCRETE, *VAPOR pressure, *TENSILE strength, *EFFECT of temperature on concrete

Abstract

In this study, the effects of heating rate and compressive strength on the spalling behavior of single-sided heated ring-restrained concrete with compressive strengths of 60 and 100 MPa were investigated. The vapor pressure and restrained stress inside the concrete were evaluated under fast- and slow-heating conditions. Regardless of the heating rate, the concrete vapor pressure and restrained stress increased as the temperature increased, and it was confirmed that spalling occurred in the 100-MPa concrete. Specifically, it was found that moisture migration and restrained stress inside the concrete varied depending on the heating rate. Under fast heating, moisture clogging and restrained stress occurred across the concrete surface, causing continuous surface spalling for the 100-MPa concrete. Under slow heating, moisture clogging occurred, and restrained stress continuously increased in the deep area of the concrete cross-section owing to the small internal temperature difference, resulting in explosive spalling for the 100-MPa concrete with a dense internal structure. Additionally, while the tensile strength of concrete is reduced by heating, stress in the heated surface direction is generated by restrained stress. The combination of stress in the heated concrete surface and the internal vapor pressure generates spalling. The experimental results confirm that heating rate has a significant influence on moisture migration and restrained stress occurrence inside concrete, which are important factors that determine the type of spalling. [ABSTRACT FROM AUTHOR]

Published

2021