Your search keyword '"rapid heating"' showing total 159 results

1. Constructing multi-scale retained austenite makes bainitic steel better mechanical properties by introducing weak chemical heterogeneity.

Author

Liu, Changbo, Sun, Dongyun, Chen, Chen, Lv, Bo, Wang, Xin, Yang, Zhinan, and Zhang, Fucheng

Subjects

BAINITIC steel, LOW alloy steel, AUSTENITE, HETEROGENEITY, BAINITE

Abstract

Overcoming the trade-off relationship between strength and ductility has always been a challenge. In this article, a neatly arranged ultrafine bainite that is composed of multi-scale retained austenite was obtained by introducing weak chemical heterogeneity in low-alloy steel. The optimized microstructure makes transformation-induced plasticity (TRIP) behavior and coordinating deformation behavior between each phase to be smoother. This results in better comprehensive properties, with 28.5% and 9% increases in uniform elongation and toughness, respectively, and a similar strength. This study provides a new way to improve the properties of low-alloy steels. A strategy of weak chemical heterogeneity has been proposed in low-alloy steel, which effectively optimizes the microstructure and enhances the plasticity and toughness of steel. [ABSTRACT FROM AUTHOR]

Published

2024

2. Constructing multi-scale retained austenite makes bainitic steel better mechanical properties by introducing weak chemical heterogeneity

Author

Changbo Liu, Dongyun Sun, Chen Chen, Bo Lv, Xin Wang, Zhinan Yang, and Fucheng Zhang

Subjects

Rapid heating, chemical heterogeneity, retained austenite, ultrafine bainite, plasticity and toughness, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Overcoming the trade-off relationship between strength and ductility has always been a challenge. In this article, a neatly arranged ultrafine bainite that is composed of multi-scale retained austenite was obtained by introducing weak chemical heterogeneity in low-alloy steel. The optimized microstructure makes transformation-induced plasticity (TRIP) behavior and coordinating deformation behavior between each phase to be smoother. This results in better comprehensive properties, with 28.5% and 9% increases in uniform elongation and toughness, respectively, and a similar strength. This study provides a new way to improve the properties of low-alloy steels.

Published

2024

3. A detailed exploration of microstructure evolution in a novel Ti–Mo martensitic steel through in-situ observation: The effect of heating rate

Author

Qing Yuan, Jiaxuan Mo, Jie Ren, Wen Liang, and Guang Xu

Subjects

Martensite, Rapid heating, Grain refinement, Precipitate, Mechanical property, Mining engineering. Metallurgy, TN1-997

Abstract

Rapid heating is a promising technique for achieving excellent mechanical properties. This study innovatively applies rapid heating to a novel Ti–Mo martensite steel through in-situ observation experiments. By comparing the microstructure evolutions at heating rates of 1 and 30 °C/s, the relationship between microstructure and property evolution was elucidated. The results indicate that the refined austenite grains resulting from rapid heating stem from enhanced grain nucleation, accumulated dislocations, and the increased formation of new carbides under the large superheat. Furthermore, carbide maturation predominates during the slow heating process, while rapid heating accelerates new carbide precipitation with limited carbide maturation. Moreover, during rapid heating, both coherent and non-coherent relationships were observed between the (Ti, Mo, Fe)C particles and the martensite matrix, demonstrating a remarkable pinning effect on grain boundary migration. Nevertheless, during slow heating, large-sized (Ti, Mo)C carbides were formed, presenting a non-coherent relationship with the martensite matrix. Additionally, the primary differences in strength caused by rapid heating compared to slow heating include grain refinement, dislocation, and precipitation strengthenings, with dislocation strengthening playing the dominant role.

Published

2024

4. Facile Synthesis and Characterization of Low-Dimensional Layered Y2O3 Nanosheets by a Rapid Heating Route.

Author

Wang, Hongjun, Yang, Shuning, Zeng, Xiong, Chen, Mengyao, Guo, Zicong, Mi, Pengtao, Zhou, Jing, and Zhu, Yuanyuan

Subjects

YTTRIUM oxides, NANOSTRUCTURED materials, X-ray diffraction, CRYSTAL structure, YTTRIUM

Abstract

Low-dimensional yttrium oxide (Y2O3) nanostructures have garnered significant research interest due to their intriguing properties arising from the dimensional effect and the modulation of the band structure. However, the simple preparation of Y2O3 nanosheets is rarely investigated due to the inherent limitations posed by the counterpart bulk cubic or monoclinic crystal structure. Herein, the low-dimensional layered Y2O3 nanosheets are prepared by a facile route of rapid heating followed by centrifugation, in which its corresponding hydrous-chloride compound is used as the sole reagent. The formation stages of layered Y2O3 nanosheets and corresponding mechanisms are elucidated in detail. The x-ray diffraction results confirm that the intermediate product after rapid heating is yttrium oxychloride (YOCl), which converts to the single-phase Y2O3 with a 2D layered phase after centrifugation. In addition, the obtained Y2O3 nanosheets possess a direct optical bandgap of 5.49 eV, and thus may hold promise for use in electronic applications. This research provides a facile and low-cost method for the preparation of other low-dimensional nanosheets with similar structures. [ABSTRACT FROM AUTHOR]

Published

2024

5. Rapid temperature response of polymer-derived SiBCN ceramics.

Author

Peng, Xudong, Zheng, Liya, Tian, Zhilin, and Li, Bin

Subjects

*AMORPHOUS semiconductors, *EXTREME environments, *TEMPERATURE effect, *TEMPERATURE, *TEMPERATURE sensors, *CERAMICS

Abstract

Polymer-derived SiBCN ceramics with good high-temperature stability and temperature-sensitive properties can be used in real-time temperature monitoring in the aeronautical industry. However, previous investigations mostly focus on the temperature sensitivity of SiBCN ceramics but neglect the fast temperature conversion of the real operating environment and its effect on the temperature sensitivity, which hinders their further practical application. In this study, the response to rapid temperature changes of polymer-derived SiBCN was studied. SiBCN ceramics maintain excellent high-temperature semiconductor performance under rapid heating, and its direct-current (DC) conductivity increases with increasing temperature. The conductive mechanism conforms to the amorphous semiconductor formula, following three different transition mechanisms in different temperature regions. The resistance of SiBCN increases with the number of cycles during 100 cycles of 500–1200 °C, presenting excellent temperature-sensitivity and relatively good sensing stability. This work demonstrates that SiBCN ceramics can maintain excellent temperature-resistance under extreme environments with rapid heating and cooling, and it is hoped that this work could guide the development of temperature sensors for extreme environments in the future. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

6. Rapid heat treatment yields excellent strength and ductility balance in a wear-resistant steel

Author

En Tang, Qing Yuan, Rui Zhang, Jie Ren, Zhongbo Li, and Guang Xu

Subjects

Rapid heating, Mechanical properties, Wear, Work hardening, Carbides, Mining engineering. Metallurgy, TN1-997

Abstract

The rapid heating treatment with different tempering temperatures of 160, 200 and 320 °C was innovatively applied in one developed martensitic wear-resistant steel. The elaborate characterization on the evolution of microstructure-mechanical properties including the wear performance in different tempering temperatures were compared. Results manifested that the rapid heating treatment yielded a peak performance in the martensitic wear-resistant steel when tempered at 200 °C, by which the tensile strength and elongation were 1762.46 MPa and 13.13%, respectively, accompanied by the highest product of strength and elongation of 23.14 GPa·%. The enhanced work hardening contribution caused by the refined martensitic laths and carbides, as well as the appropriate recovery leaded to the peak performance at 200 °C. However, the mechanical properties both deteriorated by tempering at 160 and 320 °C subjecting to either the stress concentration or the coarsen carbides. Besides, the Baker–Nutting relationship between carbides and the matrix was established and furtherly proved the coarsen carbides resulted in the worst elongation by tempering at 320 °C. In addition, the main strength differences caused by different tempering temperatures were the grain refinement strengthening, dislocation strengthening, and precipitation strengthening, in which the grain refinement and precipitation strengthening played the dominating role. The current findings provide foundation for the industrial application of rapid heating techniques on the high-performance martensitic wear-resistant steels.

Published

2024

7. Facile Synthesis and Characterization of Low-Dimensional Layered Y2O3 Nanosheets by a Rapid Heating Route

Author

Wang, Hongjun, Yang, Shuning, Zeng, Xiong, Chen, Mengyao, Guo, Zicong, Mi, Pengtao, Zhou, Jing, and Zhu, Yuanyuan

Published

2024

8. Evolution of ultrafine bainite microstructure during rapid heating process and the role of retained austenite

Author

Changbo Liu, Qiwen Fang, Jianjun Wang, Hongguang Li, Xubiao Wang, Dongyun Sun, Zhinan Yang, and Fucheng Zhang

Subjects

Ultrafine bainite, Rapid heating, Phase transformation, Austenite memory effect, Retained austenite, Mining engineering. Metallurgy, TN1-997

Abstract

Rapid heat treatment is an important method to improve the properties of steel. Moreover, the study of the phase transformation process plays an important role in the formulation of rapid heat treatment. This paper investigates phase transformation behavior and microstructure evolution of ultrafine bainite at varying heating rates, and reveals the influence mechanism of retained austenite on austenitizing. Results showed that the decomposition of retained austenite was influenced by the diffusion of Si element. Therefore, the decomposition temperature of retained austenite is severely affected by the heating rate. Retained austenite completely transformed into cementite and ferrite when heating rate was below 5 °C/s. A small amount of retained austenite was kept when the heating rate was higher than 5 °C/s. The kept austenite effectively suppressed the hysteresis of Ac1 and resulted in a unique mechanism of austenite grain formation. When the heating rate range was 5–10 °C/s, some new austenite skipped the nucleation process and grew directly on the kept austenite, forming the large austenite grains. And other new austenite was obtained via nucleation and growth process. Thus, the grain size of bimodal distribution is formed. This leads to the phenomenon of austenite memory effect. When the heating rate was increased to 50 °C/s and higher, the austenite grain size was less than 14 μm. Therefore, rapid heating makes the phase transition lag. When the heating rate is high enough, part of the austenite is kept, which has an important influence on austenitizing process of the steel.

Published

2023

9. Effects of rapid heating on the phase transformation and grain refinement of a low-carbon mciroalloyed steel

Author

Qing Yuan, Jie Ren, Jiaxuan Mo, Zhicheng Zhang, En Tang, Guang Xu, and Zhengliang Xue

Subjects

Rapid heating, Grain refinement, Carbides, Dislocations, Ultrafine steel, Mining engineering. Metallurgy, TN1-997

Abstract

The present study aims to clarify the possibility of rapid heating in the preparation of low-carbon ultrafine (UFG) steel. The effects of heating rate on the phase transformation, microstructure and precipitation of a low-carbon microalloyed steel were elaborately investigated. The results manifest that rapid heating potentially provides a simple and innovative process for the preparation of UFG steels just by increasing the heating rate. The parent austenite grains were refined due to the more reserved (Nb, Ti, V)C precipitates and dislocations within a short heating process by rapid heating. However, an effective holding time was proposed in the rapid heating to ensure the refined austenite grains. Moreover, the synthetic influences of initial increased grain boundaries and redissolved (Nb, Ti, V)C carbides provoked the abnormal grains with weakened thermostability. Redissolution of (Nb, Ti, V)C carbides were apparent during austenite nucleation at a slow heating rate, and it was verified during the isothermal holding stage by rapid heating. In addition, the austenitic phase transition occurred at higher temperature with the increase of heating rate, by which the transformation rate was accelerated.

Published

2023

10. Intercalated Multilayer Graphene with Ultra Low Resistance for Next-Generation Interconnects.

Author

Huang, Jian-Zhi, Chang, En-Cheng, Tsao, Po-Chou, Ni, I-Chih, Li, Shu-Wei, Chan, Yu-Chen, Yang, Shin-Yi, Lee, Ming-Han, Shue, Shau-Lin, Chen, Mei-Hsin, and Wu, Chih-I

Abstract

In recent years, many reports have demonstrated the high potential for multilayer graphene in semiconductor fabrication. As interconnects within semiconductors or electrodes for two-dimensional transistors, the preparation of large-area multilayer graphene is becoming increasingly important. Herein, we report a method for growing large-area multilayer graphene, which can achieve rapid heating and cooling. With the use of a high carbon concentration source, the preparation of multilayer graphene can be completed in a few seconds. This manufacturing method has the advantage of producing graphene with high quality, uniformity, and electrical conductivity. In commercial applications, this technology has great potential for the mass production and rapid fabrication of multilayer graphene. In addition, we found that the multilayer graphene produced by this method had cobalt atoms doped into the multilayer graphene during the process, resulting in its low resistivity. Combined with our intercalation technology, intercalated FeCl3 in the graphene interlayer can reduce the resistivity of graphene to 3.55 μΩ cm, which is very close to the resistivity of copper bulk. This result makes multilayer graphene more promising for various applications. [ABSTRACT FROM AUTHOR]

Published

2023

11. Applying rapid heating for controlling thermal displacement of CNC lathe

Author

Van-The Than, Chi-Chang Wang, Thi-Thao Ngo, and Guan-Liang Guo

Subjects

rapid heating, cnc lathe, thermal displacement, ball screw, temperature control, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

Thermal error always exists in a machine tool and accounts for a large part of the total error in the machine. Thermal displacement in X-axis on a CNC lathe is controlled based on a rapid heating system. Positive Temperature Coefficient (PTC) heating plates are installed on the X-axis of the machine. A control temperature system is constructed for rapid heating which further helps the thermal displacement to quickly reach stability. The system then continuously maintains stable compensation of the thermal error. The presented rapid heating technique is simpler than the compensation of machine thermal errors by interference in the numerical control system. Results show that the steady state of the thermal displacement in the X-axis can be acquired in a shorter time. In addition, almost all thermal errors in constant and varying working conditions could be significantly reduced, by above 80% and 60%, respectively, compared to those without using the rapid heating. Therefore, the proposed method has a high potential for application on the CNC lathe machine for improving its precision.

Published

2022

12. Effect of initial microstructure on microstructure and properties of bainitic steels achieved by rapid heat treatment.

Author

Liu, Changbo, Sun, Dongyun, Fang, Qiwen, Wang, Jianjun, Gao, Xiaojun, Zhang, Xinyao, Li, Guangsheng, Feng, Xiaoyong, Yang, Zhinan, and Zhang, Fucheng

Subjects

*BAINITIC steel, *LOW alloy steel, *STRAINS & stresses (Mechanics), *BAINITE, *TENSILE strength

Abstract

Rapid heat treatment is essential in manufacturing advanced high-strength steels. The initial microstructure significantly influences the steel's microstructure and properties after rapid heat treatment. The present study investigated how the initial microstructure affected phase transformation, microstructure, and properties of bainite in high-carbon low-alloy steel during rapid heat treatment. Under rapid heating, ultrafine bainite (UB) sample with homogeneous composition exhibits the lowest austenitization temperature, while globular pearlite (GP) sample with poor composition homogeneity has a higher austenitization temperature. After rapid heat treatment, the compositional distribution of the initial microstructure was partially retained in the final sample. The increase of alloying elements inhibits the nucleation of bainitic ferrite, making it easier for bainitic ferrite to grow at low-alloy positions. Finally, a large amount of retained austenite is obtained in the alloying element-rich area. The difference in microstructure results in samples with different initial microstructures having similar strengths but differing plasticities. In samples with an initial lamellar pearlite (LP) microstructure, there was a substantial amount of thicker, filmy retained austenite, with an average thickness of 96.8 nm. This led to a small increase in Kernel Average Misorientation (KAM) with strain during the tensile process. This improvement in coordinated deformation during straining indicates that the sample has achieved excellent performance, with a tensile strength of 1483 MPa and a uniform elongation of 23 %. When the initial microstructure was GP, the sample contained a large amount of crumbly retained austenite with a low aspect ratio. This structure poorly coordinated deformation with higher strain, resulting in numerous microcracks. [ABSTRACT FROM AUTHOR]

Published

2024

13. Insight into impact of co-pyrolysis process parameters on cross-interaction of volatiles between furfural residue and coal via rapid infrared heating.

Author

Zeng, Yongfu, Liu, Zuohua, Hu, Erfeng, Yu, Jianglong, Xiong, Qingang, Tian, Yishui, and Li, Shuai

Subjects

*INFRARED heating, *POROSITY, *ENERGY consumption, *KETONES, *CARBONYL group, *FURFURAL

Abstract

The energy utilization of furfural residue is an effective way for the clean production and carbon emission reduction of the furfural industry. In this study, the co-pyrolysis behaviors and products distribution of furfural residue and long flame coal were investigated via TG-FTIR-GC/MS and infrared fast heating technique. According to the analysis of TG-FTIR-GC/MS, the functional groups of carbonyl, phenolic and alkyl were generated with the co-pyrolysis process. As the temperature rose from 500 to 800 °C, the yield of oil increased from 15.27 to 18.24 wt% before decreasing to 16.64 wt%. With the increase in heating rate, the yield of oil increased first from 18.24 to 20.90 wt% and then decreased to 16.70 wt% at 40 °C/s. RSM was employed to optimize the oil yield and the highest oil content of 21.73 wt% was obtained at 650 °C and 30 °C/s. The analysis of GC-MS shows that elevating the temperature and heating rate decreased the content of ketone, phenol, ether, and furan. In addition, the result of simulated distillation shows that the total content of light fractions of oil is between 71.86 % and 77.16 % at all co-pyrolysis conditions. The evolution of char structure was analyzed by Raman, EPR and BET. The higher temperature and heating rate promoted the deoxidation of char to form carbon-centered radicals and developed pore structures. The findings may yield useful insights into the synergistic mechanism of co-pyrolysis between long flame coal and furfural residue, thereby enhancing our comprehension and facilitating future commercial applications. • Co-pyrolysis synergistic effects of coal and furfural residue were analyzed systematically. • Higher temperatures promoted the cleavage of C-O, C-H and β-O-4 to produce radicals. • Co-pyrolysis enhanced oil yields up to 21.73 wt% with over 70 % light fractions. • Infrared fast heating developed pore structures promoting the deoxidation of char. [ABSTRACT FROM AUTHOR]

Published

2024

14. Realizing the Rapid Crystallization of YBa2Cu3O7-δ Films on LaMnO3 Buffer Layer by Induction Heating.

Author

Shen, Jia-Ji, Liu, Zhi-Yong, Chen, Jing, Zhou, Xing-Hang, Li, Yu-Gang, and Cai, Chuan-Bing

Subjects

*INDUCTION heating, *BUFFER layers, *SUPERCONDUCTING films, *CRYSTALLIZATION, *DISCONTINUOUS precipitation, *THIN films, *COPPER films

Abstract

YBa2Cu3O7-δ (YBCO) thin films were fabricated rapidly on LaMnO3/MgO/Y2O3/Al2O3/Hastelloy substrate by the self-built induction heating system. The growth rate can be more than 60 nm/s, which is much higher than the traditional Metal Organic Deposition (MOD) method. The effects of heating rate, oxygen partial pressure and growth temperature on the texture and morphology of YBCO films were studied, as well as the analysis of properties. The results of X-Ray Diffraction and Scanning Electron Microscopy demonstrated that rapid heating can effectively reduce the residual of BaCO3 particles. The faster heating rate results in a faster YBCO growth rate, easier c-axis oriented grains growth and denser morphology. Moreover, the growth temperature and atmosphere window of YBCO films were obtained in the rapid heating condition. Meanwhile, the YBCO nucleation and growth models were established. This work realized the rapid crystallization of YBCO films by induction heating system and improved understanding of the nucleation mechanism of YBCO on the flexible metal substrate with buffer layers, which is extremely attractive for the industrialization development of Fluorine Free-MOD superconducting films in the future. [ABSTRACT FROM AUTHOR]

Published

2022

15. Effects of Rapid Infrared Heating and Cryogenic Cooling on the Tensile Properties and Fracture Behavior of Al-Cu-Mg

Author

Mitra Ghannadi, Hediye Hosseini, Bagher Mohammad Sadeghi, Bahman Mirzakhani, and Mohammad Tahaaha Honaramooz

Subjects

rapid heating, cryogenic treatment, precipitation hardening, al- cu-mg, tensile properties, fractography., Technology

Abstract

The objective of the present paper is to investigate the effects of rapid heating and cryogenic cooling on on the microstructure and tensile properties of Al-Cu-Mg. The specimens were subjected to three heat treatment cycles in which the Infrared heating (IR) were used as the heating medium at the ageing stage, and the liquid nitrogen and water were used as the quenching mediums. The ageing temperature and time were 190⁰C and from 2 hours to 10 hours, respectively.The results indicated that by using IR at the ageing stage, the hardening rate enhanced because the rapid heating via this method leads to faster diffusion of the alloying elements. Moreover, the high density of nano-sized precipitates formed during ageingleads to higher strength and suitable ductility. Cryogenic treatment showed a negligible effect on both microstructure and tensile properties; however, it improved ductility. Overall, the combination of a high heating rate and cryogenic treatment led to the highest mechanical properties. SEM micrograph of the fracture surface of alloy demonstrated that in Cryogenic treatment+Artificial Ageing (CAA) condition, the surface had been fully covered by deep dimples in contrast to the Cryogenic treatment+Infrared Heating (CIR) and Water-Quench+ Infrared Heating (QIR) conditions which their dimples were shallow and also some facets were observed.

Published

2021

16. Experimental investigation on the effect of open fire on the tensile properties and damage evolution behavior of granite.

Author

Yin, Tubing, Yang, Zheng, Wu, You, Tan, Xiaosong, and Li, Mingjian

Subjects

*GRANITE, *FIRE exposure, *SCANNING electron microscopes, *ROCK properties, *TENSILE strength, *TUNNEL ventilation

Abstract

The stability of rock mass after fire is a concern of many engineering projects. In this paper, the effects of open fire and different cooling methods on granites were investigated. The static Brazilian test, dynamic Brazilian test, and P-wave velocity test were carried out to evaluate the mechanical properties and damage evolution behavior. A high-speed camera is employed to monitor the failure process of rock. The microstructures of the treated granites were observed by scanning electron microscope (SEM). The results showed that the fire duration and cooling treatment have a significant effect on the P-wave velocity, static nominal tensile strength, and dynamic nominal tensile strength of granite. These characteristics decrease rapidly during 0 to 10 min, and slowly decrease after 20 min. Compared to the air-cooling treatment, the water-cooling treatment has greater damage to the heated granite. To better understand the results, the rapid heating process of open fire heating was simulated using Abaqus software. The results reveal that there is a thinner compressive stress zone at the bottom of the specimen, and there is a large zone in the middle of the sample with higher tensile stress. The crack extension would be expanded due to high tensile stress, leading to the reduction of the tensile strength of the rock. This paper aims to better predict the degree of damage of rock materials after actual fire, as well as preliminarily explore the effect of the fire exposure duration and fire extinguishing method on the tensile properties of rock. [ABSTRACT FROM AUTHOR]

Published

2022

17. Rapid and highly sensitive gas sensing with La-doped SnO2 hollow nanospheres towards NO2 detection at room temperature.

Author

Li, Yongrui, Meng, Fanjian, Yan, Xiaohui, Han, Chenshuai, Sun, Haoming, and Yang, Minghui

Subjects

*METAL oxide semiconductors, *STANNIC oxide, *GAS detectors, *CONDUCTION bands, *HEAT treatment

Abstract

The constant challenges associated with metal oxide semiconductor (MOS) gas sensors, such as high operating temperature, low gas-sensing response, and prolonged recovery time towards NO 2 restrain their practical application. Herein, we put forward a novel thought via utilizing the synergistic interplay between La doping modification and chip rapid heating treatment to solve these drawbacks. Wherein, the 3 at% La-doped SnO 2 nanospheres treated at 200℃ by rapid chip heating (referred to as 3LS-200 NSs) exhibited exceptional performance. At room temperature, these nanospheres demonstrated a highly sensitive response of 3008–20 ppm NO 2 within a rapid response time of 9 seconds. Furthermore, this sensor exhibited a low detection limit of 200 ppb and long-term stability. The oxygen vacancy content of 3LS-200 NSs increased by 10.8 % compared with that prepared by normal heating treatment (3LS-200NH NSs) with slow heating rate. The exceptional gas sensing properties of 3LS-200 NSs towards NO 2 can be primarily attributed to the increase of oxygen vacancies, resulting in a reduced bandgap and the Fermi level shift of 0.07 eV toward the conduction band edge, hence enhancing surface electron transfer capability. This work presents a simple and energy-efficient strategy for commercial NO 2 detection. [Display omitted] • The La-doped SnO 2 hollow nanospheres were synthesized via a facile one-step hydrothermal method and rapid chip heating. • The La doping and rapid chip heating pretreatment contributed to efficient NO 2 detection. • The enhanced NO 2 gas sensing performance was explained by oxygen vacancies modulation and band structure adjustment. [ABSTRACT FROM AUTHOR]

Published

2024

18. Study on Filling Capacity of Optical Glass in a Novel Rapid Hot Embossing Process.

Author

Li, Jianzhi, Gong, Feng, Wang, Xin, and Yang, Gao

Subjects

OPTICAL glass, TEMPERATURE control, TEMPERATURE distribution, SILICON carbide, GLASS

Abstract

This paper aims to present a novel rapid hot embossing approach and to study filling capacity of optical glass in the hot embossing process. Firstly, a novel rapid hot embossing device is developed, which consists of a rapid heating module and a precision loading module. Particularly, the rapid heating module allows a maximum temperature of 800 °C and a heating rate of 300 °C/min, with decent temperature control accuracy and uniform temperature distribution. In hot embossing process, by incompletely filling the microhole of silicon carbide mold, a microlens would be formed on the surface of glass disc, and the filling capacity of glass is quantified by the maximum height of the microlens. The tailor-made hot embossing device was exploited to conduct a series of experiments for evaluating effects of process parameters on the filling capacity of N-BK7 glass. Experimental results indicate that the filling capacity of glass could be enhanced by increasing the embossing force, the embossing temperature, the soaking time but decreasing the annealing rate. Furthermore, compared to soaking time and annealing rate, embossing force and embossing temperature have more significant influence on the filling capacity of N-BK7 glass. Therefore, the novel rapid hot embossing is a practical and promising technology for fabricating microstructures on glass materials with high softening points. [ABSTRACT FROM AUTHOR]

Published

2022

19. DC electric field‐assisted hot pressing of zirconia: Methodology, phenomenology, and sintering mechanism.

Author

Xu, Jingkun, Liu, Zetan, Xie, Zhipeng, He, Shan, and Xi, Xiaoqing

Subjects

*HOT pressing, *YTTRIA stabilized zirconium oxide, *SINTERING, *ATOMIC force microscopy, *ZIRCONIUM oxide, *CARRIER density

Abstract

Flash sintering (FS) is an important technique in the field of ceramic sintering. Nevertheless, conventional FS is less attractive for practical applications because of the complex shapes and small sizes of the specimens. In this study, using the novel electric field‐assisted hot pressing (FAHP) technique, we successfully achieved FS during the net‐shape hot pressing (HP) process for the first time. It was found that the 3 mol% yttria‐stabilized zirconia (3YSZ) can be flash sintered at 909°C using a fairly low DC field of 33 V/cm under 30 MPa pressure. The grain sizes of the FAHP‐sintered samples were 20% smaller than that of the HP‐sintered sample. When the current density limit is ≥240 mA/mm2, 3YSZ can be fully densified during the flash events. Careful analysis of the sintering curves suggests that although the carrier type or concentration is changed during flash events, it cannot explain the ultrafast densification. Additionally, we devised a qualitative method to analyze the densification mechanism. The results indicated that the ultrafast densification observed during flash events resulted from the synergistic effects of the rapid heating rate and peak sample temperature. Finally, the atomic force microscopy confirmed the lower grain boundary energy for the FAHP‐sintered samples, which accounts for the smaller grain sizes than the HP‐sintered sample. We believe that the FAHP technique could create new possibilities for theoretical and applied research on field‐assisted sintering techniques. [ABSTRACT FROM AUTHOR]

Published

2021

20. Effects of Rapid Infrared Heating and Cryogenic Cooling on the Tensile Properties and Fracture Behavior of Al-Cu-Mg.

Author

Ghannadi, Mitra, Hosseini, Hedieh, Sadeghi, Bagher Mohammad, Mirzakhani, Bahman, and Honaramooz, Mohammad Taha

Subjects

INFRARED heating, THERMODYNAMIC cycles, NITROGEN in water, COOLING, HEAT treatment, PRECIPITATION hardening, TENSILE tests

Abstract

The objective of this work was to investigate the effect of rapid heating and cryogenic cooling on the fracture and tensile properties of Al-Cu-Mg samples. The specimens were subjected to three different heat treatment cycles in which the Infrared heating (IR) were used as the heating medium at the ageing stage, and the liquid nitrogen and water were used as the quenching mediums. The ageing temperature and time were 190⁰C and from 2 - to 10h respectively. The results indicated that by using IR at the ageing stage, the hardening rate enhanced because the rapid heating via this method led to faster diffusion of the alloying elements. Moreover, the high density of nanosized precipitates formed during ageing was another reason for higher strength and ductility. Cryogenic treatment had a negligible effect on both the microstructure and tensile properties. However there was an improvemnet in the ductility to some extent. Overall, the combination of a high heating rate and cryogenic treatment led to the highest mechanical properties. SEM micrographs of the fracture surface demonstrated that in Cryogenic treatment plus Artificial Ageing (CAA) condition, the surface was fully covered by deep dimples in contrast to the Cryogenic treatment plus Infrared Heating (CIR) and Water-Quench plus Infrared Heating (QIR) conditions which contained shallwer dimples. Some facets were also observed in the latter samples. [ABSTRACT FROM AUTHOR]

Published

2021

21. Onset of heterogeneous nucleation in pool boiling of HFE-7100 following rapid heating on a microscale heater.

Author

Lankry, Amiav, Koyfman, Alex, Haustein, Herman D., Nir, Yaakov, Ziskind, Gennady, and Bar-Kohany, Tali

Subjects

*EBULLITION, *HETEROGENOUS nucleation, *PHASE transitions, *NUCLEATE boiling, *HEATING, *ELECTRONIC equipment, *INK-jet printers

Abstract

• A unique experimental apparatus was built to study rapid phase transition. • • HFE-7100 ON data for at high heating rates, 106 K/s, are measured for the 1st time. • • Results are obtained in the intermediate heating rates regime (105 to 106. • K/s). • • Maximum superheating degree of 14 K was obtained for a heating rate of 2.2・106 K/s. • • For slower heating rates, superheating spans 12 K for water and 4 K for HFE-7100. Effective thermal management of electronics is crucial for maintaining their reliability, longevity, and optimal performance. As electronic devices become increasingly compact and powerful, the need to explore new and innovative methods for thermal management becomes ever more critical. Rapid transitions of power lead to temperature spikes (hotspots) of up to 100 K, and thus can dramatically increase the failure occurrence of chips. Power spikes imply that heterogeneous nucleation occurs due to rapid heating, which can vary between 104 – 106 K/s, and hence the coolant is in its metastable region under various degrees of superheating. Gaining ONB data with respect to the heating rate holds significance for diverse applications including nuclear installations, engines, inkjet printers, and laser-based systems. In the present paper, we have refined the definition to a heterogeneous nucleation event due to a rapid heating process, that occurs when the timescale for the wall heating is shorter than the critical bubble's significant growth time. Data pertaining to the dependence of the onset of nucleate boiling (ONB) on the heating rate is presented for the first time. Experiments are performed with HFE-7100 fluid that is rapidly heated using a uniquely designed micro-heater, 122 × 234 μm2 in size. The newly designed and constructed system facilitates precise measurements of fast heating processes. In this study, we conducted a series of experiments spanning heating rates from 104 to ∼106 K/s. This range of heating rates was identified in our previous studies as an intermediate regime for water. The region of intermediate heating rates was previously proved in our research to be challenging to attain, due to the varying stability of the metastable zone; it is primarily attributed to pre-existing nucleation sites. Consequently, this led to a notable gap in the experimental results for water, within this particular region, in the literature. Notably, in the current study, we were able to achieve a maximum superheating degree of 14 K at a heating rate of 2.2·106 K/s. Preheated liquids reach the same superheating degree with different heating rates, depending on the coexistence and spinodal curves. It was found that water and HFE-7100 differ significantly in their metastable zone, and that the first zone, for slower heating rates, spans approximately 12 K for water, but only 4 K for HFE-7100. [ABSTRACT FROM AUTHOR]

Published

2024

22. Realizing the Rapid Crystallization of YBa2Cu3O7-δ Films on LaMnO3 Buffer Layer by Induction Heating

Author

Shen, Jia-Ji, Liu, Zhi-Yong, Chen, Jing, Zhou, Xing-Hang, Li, Yu-Gang, and Cai, Chuan-Bing

Published

2022

23. Study on Filling Capacity of Optical Glass in a Novel Rapid Hot Embossing Process

Author

Jianzhi Li, Feng Gong, Xin Wang, and Gao Yang

Subjects

hot embossing, optical glass, rapid heating, filling capacity, microlens, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This paper aims to present a novel rapid hot embossing approach and to study filling capacity of optical glass in the hot embossing process. Firstly, a novel rapid hot embossing device is developed, which consists of a rapid heating module and a precision loading module. Particularly, the rapid heating module allows a maximum temperature of 800 °C and a heating rate of 300 °C/min, with decent temperature control accuracy and uniform temperature distribution. In hot embossing process, by incompletely filling the microhole of silicon carbide mold, a microlens would be formed on the surface of glass disc, and the filling capacity of glass is quantified by the maximum height of the microlens. The tailor-made hot embossing device was exploited to conduct a series of experiments for evaluating effects of process parameters on the filling capacity of N-BK7 glass. Experimental results indicate that the filling capacity of glass could be enhanced by increasing the embossing force, the embossing temperature, the soaking time but decreasing the annealing rate. Furthermore, compared to soaking time and annealing rate, embossing force and embossing temperature have more significant influence on the filling capacity of N-BK7 glass. Therefore, the novel rapid hot embossing is a practical and promising technology for fabricating microstructures on glass materials with high softening points.

Published

2022

24. High-efficiency flow-through induction heating.

Author

Kilic, Veli Tayfun, Unal, Emre, and Volkan Demir, Hilmi

Subjects

HEATING, INDUCTION heating, PLASTIC pipe, HEAT transfer, ENERGY transfer, CALORIMETRY

Abstract

This study reports a newly designed induction heating system for efficient, fast, and safe flow-through heating. The system has a very simple architecture, which is composed of a transmitting coil, an isolating plastic pipe, and an embedded metal shell. Wireless energy transfer from the external coil to the internal metal shell through the pipe is essential for decreasing losses. Also, a large contact surface between a fluid and the immersed shell enables rapid heat transfer. The proposed heating system was systematically investigated for different shell geometries and the results were compared with a commercially available conductive flow-through heating device. As a proof-of-concept demonstration, a prototype of the designed induction heating system was manufactured and the heating measurements were conducted with water. Power transfer efficiency of the prototyped induction heating system was measured to be 97%. The comparative study indicates that such high-efficiency induction flow-through heating system offers a great potential for replacing the conventional conductive heating device used in household applications in which the rapid and compact heating is desired. [ABSTRACT FROM AUTHOR]

Published

2020

25. Interferometric Study of the Heat Transfer Phenomena Induced by Rapid Heating of Nickel Sheet.

Author

Seo, Hyeon-Seok, Hwang, In-Ju, and Kim, Youn-Jea

Subjects

HEAT transfer, COMPRESSIVE force, HEAT, NUSSELT number, FORCED convection

Abstract

Visualization of the heat transfer phenomena induced by the rapid heating of nickel sheets was carried out using a Mach–Zehnder interferometer (MZI) and a high-speed camera. This phenomenon may be an important factor in heat transfer phenomena when the working fluids reach the thermodynamic critical point. The effect of heat transfer on the heating conditions of a nickel sheet was quantified by finite fringe analysis. The results show that isotherms near the heating surface with rapid heating are generated, and the induced isotherms are moved upward with similar patterns for different heating conditions. In addition, it is confirmed that the local Nusselt number decreases to the relationship of a secondary function if the thickness of the metal specimen is very thin and the time to reach the highest temperature is very short. Moreover, it decreased according to the increase of heating energy because the heat transfer mainly occurred by conduction and radiation rather than by convection, because the expansive force and compressive force between the fluid layers on the wall increased due to an increase in the heating energy in the beginning. [ABSTRACT FROM AUTHOR]

Published

2020

26. Warm stamping of ultra-high strength steel sheets at comparatively low temperatures using rapid resistance heating.

Author

Mori, Ken-ichiro, Abe, Yohei, and Miyazawa, Sadao

Subjects

*LOW temperatures, *SHEET steel, *HEATING, *RESISTANCE heating, *FURNACES, *CORROSION resistance

Abstract

A warm stamping process of 1 and 1.2 GPa ultra-high strength steel sheets at comparatively low temperatures using rapid resistance heating was investigated to produce high strength parts. The effects of the heating temperature and rate on mechanical and surface properties of warm-stamped parts were examined. For a rapid heat rate of 100 °C/s around a heating temperature of 300 °C, the hardness of the formed parts increased from that of the as-received sheets, and the hardness for the 1.2 GPa sheet approached that of conventional hot-stamped parts from 22MnB5 steel sheets. The increase in hardness appeared only for rapid heating, and not for slow heating using a furnace. The increase in hardness is due to the transformation of retained austenite into martensite at comparatively low temperatures using rapid resistance heating and cooling. For the comparative low heating temperature, the non-coated sheet hardly oxidised, and the galvannealed sheet having high corrosion resistance did not exhibit the exfoliation of the coating layer, whereas the springback did not improve. [ABSTRACT FROM AUTHOR]

Published

2020

27. MICROSTRUCTURAL IMAGE ANALYSES OF MILD CARBON STEEL SUBJECTED TO A RAPID CYCLIC HEAT TREATMENT.

Author

Aghogho, Orhadahwe Thomas, Akanni, Adeleke Adekunle, Olayiwola, Aweda Jacob, Pelumi, Ikubanni Peter, and Odusote, Jamiu Kolawole

Subjects

*MILD steel, *CARBON steel, *HEAT treatment, *IMAGE analysis, *CARBON analysis

Abstract

The study is focused on using an image analysis to explain the effects of several cycles of rapid heat treatment on the microstructure of 0.213 wt. % carbon steel. The samples examined are subjected to a diffusional heat treatment followed by several cycles of a rapid heat treatment. The process of the diffusional heat treatment involves heating the samples from an ambient temperature to 850oC in an electric muffle furnace for 56 min and then quenching in running water. In order to improve further the mechanical properties of the heat treated samples, they are subjected to several cycles of rapid heating. Each cycle comprises preheating the furnace to 900oC prior to the samples charging. The treated samples are subjected to a microstructural examination using optical microscopy followed by an image analysis using Image J software. The mechanical properties of the heat treated samples are characterized through ultimate tensile, hardness and impact tests. The results reveal that the grain size decreases from 1.07 µm in the control sample to 0.79 µm in the three-cycle sample and increases to 0.86 µm in the four-cycle one. It is also observed that the two-cycle sample shows the highest ductility (15356.3 N/mm2) and the lowest ultimate strength (833.375 N/mm2). This implies that the two-cycle rapid heat treatment is required for grain refinement in mild carbon steel. [ABSTRACT FROM AUTHOR]

Published

2020

28. Development and Demonstration of a High Efficiency, Rapid Heating, Low NOx Alternative to Conventional Heating of Round Steel Shapes, Steel Substrate (Strip) and Coil Box Transfer Bars

Author

Wagner, John

Published

2010

29. Suppression of crystallization in ZBLAN glass by rapid heating and cooling processing.

Author

Ong, Teng‐Cheong, Fogarty, Ben, Steinberg, Ted, Jaatinen, Esa, and Bell, John

Subjects

*FLUORIDE glasses, *FOOD pasteurization, *HEAT conduction, *TRANSMISSION electron microscopy, *GLASS, *CRYSTALLIZATION

Abstract

ZBLAN glass is a heavy metal fluoride glass that tends to undergo heavy devitrification, resulting in a crystalline material. It has many applications, including its use as an optical waveguide for fiber‐optic technology. However, when the glass is processed with traditional casting techniques, crystallites form readily that act as scattering centers, which results in large attenuation losses. In this study, it has been experimentally demonstrated that processing ZBLAN rapidly with a heating rate of 25 000 K/min and cooling rate of 4000 K/min yields test samples that are fully amorphous and retain a disordered molecular arrangement characteristic of its molten state. This novel method was developed using a specifically designed equipment named a Rapid Electro‐thermal Processing Device, or "REPD." The REPD applies ohmic heating and thermal conduction to a heat sink to rapidly process the ZBLAN material. The absence of crystallites in the rapidly processed ZBLAN test samples were verified using transmission electron microscopy (TEM) analysis. Applying a theoretical algorithm, the critical cooling rate for yielding fully amorphous ZBLAN glass was determined to be 1081 K/min for a sample volume of 9.4 × 10−8 m3. [ABSTRACT FROM AUTHOR]

Published

2019

30. Transient boiling flow in 5 × 5 rod bundle under non-uniform rapid heating.

Author

Takiguchi, Hiroki, Furuya, Masahiro, Arai, Takahiro, and Shirakawa, Kenetsu

Subjects

*ATMOSPHERIC pressure measurement, *BOILING water reactors, *NUCLEAR fuels, *WATER vapor, *THERMAL expansion

Abstract

Highlights • An atmospheric pressure experiment loop with 5 × 5 bundle containing 3 × 3 heat-generating bundle with heating length of 450 mm as the test part was fabricated. • We visualized void behavior and measured the local void fraction, the time-averaged void fraction and the initial bubble detection time were quantified for the transient boiling behavior when the heat output of the bundle changes rapidly in the order of milliseconds. • The relationship between the transverse flow range of bubbles transiently and the bundle heat output was verified. Abstract Rapid thermal elevation in boiling water reactor (BWR) is an important factor for nuclear safety and there is a need to develop an analysis code for the transient phenomenon and its validation process. To evaluate the thermal property of transient boiling and its uncertainty, corroborative experimental information is crucial. In particular, the lateral propagation behavior of a vapor bubble (void) in the cross-sectional direction of fuel assembly has yet to be determined. This study evaluates the void propagation behavior in a 5 × 5 rod bundle with cross-sectional heat distribution that causes only the 3 × 3 rod bundle to generate heat; assuming rapid heating under atmospheric pressure. In this paper, using the maximum heat output applied to the nine heated rods as a parameter, from the visualization of the void behavior and the measurement of the local void fraction, the heat output conditions under circumstances where lateral propagation of voids occurs and where voids are only localized in the heated region are summarized. We quantified the time difference initially detected and the time-averaged void fraction according to the lateral propagation level. [ABSTRACT FROM AUTHOR]

Published

2018

31. Investigation on spalling resistance of ultra-high-strength concrete under rapid heating and rapid cooling

Author

Sun Bei and Lin Zhixiang

Subjects

Ultra-high strength concrete, Spalling resistance, Polypropylene fiber, Rapid heating, Rapid cooling, Mechanism, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Effects of the fiber type, dosage and length on the explosive spalling of ultra-high-strength concrete under rapid heating and rapid cooling were experimentally investigated. The mechanism of spalling resistance was examined by comprehensive thermal analysis, X-ray diffraction analysis, scanning electron microscopy and mercury porosimetry. The burst time is extended but the spalling is unaffected by the addition of steel fiber. The spalling resistance is improved with the addition of polypropylene (PP) fiber or PP and steel fibers. Ultra-high-strength concrete with 0.20% (vol.) PP fiber has excellent spalling resistance. The resistance to explosive spalling is enhanced with 12- or 19-mm-long PP fibers. PP fiber improves the spalling resistance mainly through the formation of tubular channels.

Published

2016

32. Interferometric Study of the Heat Transfer Phenomena Induced by Rapid Heating of Nickel Sheet

Author

Hyeon-Seok Seo, In-Ju Hwang, and Youn-Jea Kim

Subjects

rapid heating, compressible fluid, thermo-acoustic phenomena, Mach–Zehnder interferometer, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Visualization of the heat transfer phenomena induced by the rapid heating of nickel sheets was carried out using a Mach–Zehnder interferometer (MZI) and a high-speed camera. This phenomenon may be an important factor in heat transfer phenomena when the working fluids reach the thermodynamic critical point. The effect of heat transfer on the heating conditions of a nickel sheet was quantified by finite fringe analysis. The results show that isotherms near the heating surface with rapid heating are generated, and the induced isotherms are moved upward with similar patterns for different heating conditions. In addition, it is confirmed that the local Nusselt number decreases to the relationship of a secondary function if the thickness of the metal specimen is very thin and the time to reach the highest temperature is very short. Moreover, it decreased according to the increase of heating energy because the heat transfer mainly occurred by conduction and radiation rather than by convection, because the expansive force and compressive force between the fluid layers on the wall increased due to an increase in the heating energy in the beginning.

Published

2020

33. Perspective of Micro Process Engineering for Thermal Food Treatment

Author

Alexander Mathys

Subjects

micro process engineering, thermal processing, food processing, preservation, thermal inactivation, rapid heating, Nutrition. Foods and food supply, TX341-641

Abstract

Micro process engineering as a process synthesis and intensification tool enables an ultra-short thermal treatment of foods within milliseconds (ms) using very high surface-area-to-volume ratios. The innovative application of ultra-short pasteurization and sterilization at high temperatures, but with holding times within the range of ms would allow the preservation of liquid foods with higher qualities, thereby avoiding many unwanted reactions with different temperature–time characteristics. Process challenges, such as fouling, clogging, and potential temperature gradients during such conditions need to be assessed on a case by case basis and optimized accordingly. Owing to the modularity, flexibility, and continuous operation of micro process engineering, thermal processes from the lab to the pilot and industrial scales can be more effectively upscaled. A case study on thermal inactivation demonstrated the feasibility of transferring lab results to the pilot scale. It was shown that micro process engineering applications in thermal food treatment may be relevant to both research and industrial operations. Scaling of micro structured devices is made possible through the use of numbering-up approaches; however, reduced investment costs and a hygienic design must be assured.

Published

2018

34. Effects of Heating and Quenching Processing Parameters on Phase Transformation of 55CrMo Steel.

Author

Liu, Haijuan, Li, Huiping, Li, Zhichao, and He, Lianfang

Subjects

HEATING, QUENCHING (Chemistry), PHASE transitions, CHROMIUM molybdenum steel, MICROSTRUCTURE, MICROHARDNESS, AUSTENITE

Abstract

Microstructure and mechanical properties after induction hardening have a significant effect on the wear resistance performance and lifetime of 55CrMo steel ball screw. In the paper, the dilatometric curves were recorded at the different heating rate by a Gleeble-1500D thermo-mechanical simulator to determine the effect of heating rate on the austenitizing temperature of 55CrMo steel. Heat treatment of some specimens was performed by the Gleeble-1500D thermal simulator at the different heating temperature, holding time and cooling rate to investigate the effect of induction hardening parameters on the phase transformation, microstructure and microhardness of 55CrMo steel. Microstructure of specimen was analyzed using an optical microscope and a scanning electron microscope. Volume fraction of retained austenite was measured using an x-ray diffractometer. The mechanical properties were evaluated by a microhardness tester. The results show that the austenitizing temperature of 55CrMo steel increases with the increasing heating rate. Increasing the heating temperature, holding time and cooling rate of specimen is helpful in obtaining a uniform cryptocrystalline martensite. Volume fraction of retained austenite is less as the heating temperature is in the range of 900-950 °C. In the induction hardening of 55CrMo steel, the heating temperature should be in the range of 900-1000 °C. [ABSTRACT FROM AUTHOR]

Published

2018

35. Quantitative study on graphitization and optical absorption of CVD diamond films after rapid heating treatment.

Author

Yan, Xiongbo, Wei, Junjun, An, Kang, Zhao, Yun, Liu, Jinlong, Chen, Liangxian, Hei, Lifu, and Li, Chengming

Subjects

*GRAPHITIZATION, *CHEMICAL vapor deposition, *DIAMOND films, *LIGHT absorption, *THERMAL shock, *HIGH temperatures

Abstract

Slightly graphitization might be incurred on CVD diamond films when suffering instantaneous high temperature thermal shock. In this paper, phase transitions of CVD free-standing diamond films have been studied experimentally at the temperature range of 1500–1800 °C through a plasma rapid heating process. Raman spectra and X-ray photoelectron spectra (XPS) are compared and discussed for the purpose of measuring the percentage of graphitic carbon component in CVD diamond films after heat treatment at different temperatures. An obvious optical degradation took place in both visible and infrared bands with the increased treating temperature. The result indicates that graphitization is dominated along grain boundaries rather than in internal grains. In addition, the nitrogen related absorption peaks were not covered by the enhanced optical absorption background, which was caused by the opaque graphitic carbon formed at high temperature. Nitrogen concentrations have also been evaluated for these graphitized diamond films and there is no evidence to show the movement or aggregation of nitrogen atoms. [ABSTRACT FROM AUTHOR]

Published

2018

36. Fast charging of lithium-ion batteries at all temperatures.

Author

Xiao-Guang Yang, Guangsheng Zhang, Shanhai Ge, and Chao-Yang Wang

Subjects

*LITHIUM-ion batteries, *TEMPERATURE, *ELECTRIC vehicles, *AUTOMOBILES, *ELECTROLYTES

Abstract

Fast charging is a key enabler of mainstream adoption of electric vehicles (EVs). None of today's EVs can withstand fast charging in cold or even cool temperatures due to the risk of lithium plating. Efforts to enable fast charging are hampered by the trade-off nature of a lithium-ion battery: Improving low-temperature fast charging capability usually comes with sacrificing cell durability. Here, we present a controllable cell structure to break this tradeoff and enable lithium plating-free (LPF) fast charging. Further, the LPF cell gives rise to a unified charging practice independent of ambient temperature, offering a platform for the development of battery materials without temperature restrictions. We demonstrate a 9.5 Ah 170 Wh/kg LPF cell that can be charged to 80% state of charge in 15 min even at -50 °C (beyond cell operation limit). Further, the LPF cell sustains 4,500 cycles of 3.5-C charging in 0 °C with <20% capacity loss, which is a 90x boost of life compared with a baseline conventional cell, and equivalent to >12 y and >280,000 miles of EV lifetime under this extreme usage condition, i.e., 3.5-C or 15-min fast charging at freezing temperatures. [ABSTRACT FROM AUTHOR]

Published

2018

37. Effects of rapid heating on non-equilibrium microstructure evolution and strengthening mechanisms of titanium alloy.

Author

Chang, Shupeng, Wang, Kehuan, Wang, Bin, Kopec, Mateusz, Li, Zhe, Wang, Liliang, and Liu, Gang

Subjects

*HEATING, *TITANIUM alloys, *TRANSITION metals, *MICROSTRUCTURE, *TENSILE tests, *TENSILE strength

Abstract

In this paper, the effects of heating parameters, including temperature ranging from 900 °C to 1000 °C, heating rates ranging from 2 °C∙s−1 to 100 °C∙s−1, and 120 s soaking on the non-equilibrium microstructure evolution of Ti-6Al-4V alloy were studied. Microstructures after heating were characterized to reveal the mechanism of non-equilibrium phase transformation. Uniaxial tensile tests at room temperature were carried out to evaluate the effects of non-equilibrium microstructure on the mechanical properties. Results show that higher heating rate and lower temperature lead to lower β phase volume fraction and finer β grains. A transition region with element gradient forms in the α p grain near the α p /β phase boundary and transfers into β phase gradually during the heating. Rapid heating could confine the movement of the transition region, and therefore reduce the α→β transition and growth of the β phase. When the Ti-6Al-4V alloy was heated to 1000 °C at a rate of 50 °C/s and then quenched immediately, the tensile strength was improved by 19.5% and reached up to 1263.0 MPa with the elongation only decreasing from 13.6% to 9.6% compared with the initial material. The main strengthening mechanism is that the rapid heating in the single-phase region avoids the rapid growth of the β phase, which leads to fully fine martensite formation after water quenching. [Display omitted] • Rapid heating reduces the element diffusion and leads to the formation of non-equilibrium microstructure. • Higher strength and ductility of Ti-6Al-4V alloy can be achieved after rapid heating in the single β-phase region. • The main strengthening mechanism is that the rapid heating in the single-phase region avoids the rapid growth of the β phase, which leads to fully fine martensite formation after water quenching. [ABSTRACT FROM AUTHOR]

Published

2023

38. Lethal Effects of High Temperatures on Brown Marmorated Stink Bug Adults before and after Overwintering

Author

Davide Scaccini, Carlo Duso, and Alberto Pozzebon

Subjects

rapid heating, temperature tolerance, halyomorpha halys, quarantine, nutrient index, heat treatment, diapause, Science

Abstract

The invasive brown marmorated stink bug, Halyomorpha halys, is causing economic and ecological damage in invaded areas. Its overwintering behavior warrants mitigation practices in warehouses and shipping operations. The aim of this study was to characterize the mortality response curves of H. halys adults to short high-temperature exposure. Here we compared field-collected individuals entering (ENA) and exiting diapause (EXA). EXA adults displayed increased susceptibility to high temperatures compared to ENA individuals. Complete mortality of all tested individuals was obtained after 10 min exposure at 50.0 °C, and after 15 (EXA) or 20 min (ENA) at 47.5 °C. The nutritional status of these insects had no effect on high-temperature tolerance. The mortality curves obtained here may be used for the definition of cost-effective heat treatments aimed at the H. halys control.

Published

2019

39. A Rapid Thermal Nanoimprint Apparatus through Induction Heating of Nickel Mold

Author

Xinxin Fu, Qian Chen, Xinyu Chen, Liang Zhang, Aibin Yang, Yushuang Cui, Changsheng Yuan, and Haixiong Ge

Subjects

thermal nanoimprint lithography, rapid heating, induction heating, nickel mold, Mechanical engineering and machinery, TJ1-1570

Abstract

Thermal nanoimprint lithography is playing a vital role in fabricating micro/nanostructures on polymer materials by the advantages of low cost, high throughput, and high resolution. However, a typical thermal nanoimprint process usually takes tens of minutes due to the relatively low heating and cooling rate in the thermal imprint cycle. In this study, we developed an induction heating apparatus for the thermal imprint with a mold made of ferromagnetic material, nickel. By applying an external high-frequency alternating magnetic field, heat was generated by the eddy currents and magnetic hysteresis losses of the ferromagnetic nickel mold at high speed. Once the external alternating magnetic field was cut off, the system would cool down fast owe to the small thermal capacity of the nickel mold; thus, providing a high heating and cooling rate for the thermal nanoimprint process. In this paper, nanostructures were successfully replicated onto polymer sheets with the scale of 4-inch diameter within 5 min.

Published

2019

40. Investigation on Influence of Rapid Heating on Austenitization of Ultra-High Strength Steel.

Author

Tao, W. J., Liang, W. K., and Zhang, Y. S.

Subjects

HIGH strength steel, AUSTENITIC steel, HEATING, HEAT treatment of steel, GRAIN size

Published

2016

41. The Evolution of Oxidation Scales on 22MnB5 Hot Press Forming Steel during Rapid Heating.

Author

Yao, S. J., Liu, W. J., Gao, W. B., Zhang, Z. W., and Ding, Y. L.

Subjects

HOT pressing, MANGANESE steel, FOIL stamping, HIGH strength steel, AUTOMOBILE steel, OXIDATION kinetics

Published

2016

42. A characterisation of tool-ply friction behaviors in thermoplastic composite.

Author

Lee, Jeong-Min, Kim, Byung-Min, Lee, Chan-Joo, and Ko, Dae-Cheol

Subjects

THERMOPLASTICS, FRICTION, COMPOSITE materials, CARBON fiber-reinforced plastics, COMPRESSION loads, BINDING agents

Abstract

Generally, the compression forming process is mainly used to fabricate the pre-form of CFRP product in resin transfer molding(RTM) process. The laminate is deformed under the low pressure because only fabrics and binders are used in pre-form process. However, the laminate consisted of prepreg is deformed under the high pressure and warm temperature to improve the surface quality and remove the voids in perperg compression forming(PCF) process. Therefore, the evaluations of tool-ply friction behaviors are required under the condition of high pressure and warm temperature. Several parameters have been investigated to determine their effect on the friction coefficient between the tool and laminate: normal pressure, laminate temperature, tool temperature, atmosphere temperature, and laminate orientation. In this study, the friction behaviors were evaluated for several important parameters of normal pressure, laminate orientation and atmosphere temperature. This paper describes two experimental method for measuring the friction behaviors of thermoplastic composites. The pull-through and rotational friction tests were performed to compare the friction behaviors according to the operating direction in the tests. In addition, the relationship of stribeck curve was evaluated under the conditions of high pressure and warm temperature. [ABSTRACT FROM AUTHOR]

Published

2017

43. A study on the process design of prepreg compression forming using rapid heating and cooling system.

Author

Lee, Jeong-Min, Kim, Byung-Min, Lee, Sang-Kon, Park, Joon-Hong, and Ko, Dae-Cheol

Subjects

HEATING, COOLING, MECHANICAL behavior of materials, MANUFACTURING processes, LAMINATED materials

Abstract

Prepreg compression forming(PCF) is well known for the manufacturing process with high mechanical properties, low equipment cost and high surface quality. Generally, the temperature difference and rapid heat transfer between the tool and laminate can lead to some problems such as heat distortion, low formability and bad surface quality. Therefore, this paper attempts to solve these problems by using the rapid heating and cooling device, similarly to injection molding. It is possible to heat the tool above T g and cool it down under T g within few minutes. Also, the defect of distortion is prevented by rapid cooling system. In this study, the manufacturing process of CFRTP B-pillar reinforcement was designed based on structural analysis and thermal forming analysis. First, the thickness of laminate satisfying the energy absorption of conventional steel product was determined through structural analysis. Second, the thermal properties of the prepreg was evaluated for the thermal forming analysis. The thermal forming analysis of CFRTP laminate was carried out to determine the holding force. Finally, B-pillar reinforcements of CFRTP were fabricated and evaluated their dimensional accuracies and shear angle. [ABSTRACT FROM AUTHOR]

Published

2017

44. Enhancing the tensile yield strength of A6082 aluminum alloy with rapid heat solutionizing.

Author

Chang, Yi-Ling, Hung, Fei-Yi, and Lui, Truan-Sheng

Subjects

*ALUMINUM alloys, *TENSILE strength, *HEATING of metals, *METAL solubility, *SOLIDIFICATION

Abstract

The major objective of the present study is to clarify the effects of rapid heat solutionizing on tensile strength of A6082 aluminum alloy. In the present investigation, grain dimensions and insoluble IMC particle were investigated both in the traditional resistance heating and in the rapidly heating specimens. Furthermore, the effect of rapid heat solutionizing on tensile strength under an identical artificial aging condition was studied pertaining to the observation on the insoluble particles present in the material due to the solidificational process and which undergone rapid heat solutionizing. The critical strain of tensile serrated flow caused by Portevin-Lechatelier (PL) effect was compared with that of the resistance heating specimens. Such rapid heating specimen is also showing larger critical onset strain in the tensile serrated flow (ɛc), suggests that the rapid heating process could offer a higher concentration on solution solutes. Hardness and tensile strength data indicated an increasing aging effect, the higher concentration of Mg and Si solid solution also lead to a shorter limiting T4/T6 process duration of A6082 aluminum alloy. A significantly shorter heat treatment time to achieve peak hardness (HRB73) without deterioration of tensile strength. The concentration of rapid heat solution was investigated using SEM and TEM, and the above results should be related to the attractive interaction between silicon and magnesium solutes since the onset strain of tensile serrated flow increases with the increasing heating rate. [ABSTRACT FROM AUTHOR]

Published

2017

45. Kinetics of the reverse martensitic transformation in shape memory alloys under an abrupt heating pulse.

Author

Vollach, Shahaf, Shlagman, Haim, and Shilo, Doron

Subjects

*SHAPE memory alloys, *MARTENSITIC transformations, *HEAT transfer, *SHEAR waves, *CHEMICAL kinetics

Abstract

The kinetics of the reverse martensitic transformation in shape memory alloy wires is studied under conditions at which it is restricted neither by the rate of heat transfer nor by mechanical inertia. Two characteristic times for the transformation are identified and estimated. A model provides a universal expression that fits all experimental measurements performed at different temperatures. The kinetic law predicted by the model indicates that interface velocities are governed by viscous resistance and are thus much slower than the shear wave speed, even under very large driving force values. [ABSTRACT FROM AUTHOR]

Published

2017

46. Heat transfer and crisis phenomena at pool boiling of liquid nitrogen on the surfaces with capillary-porous coatings.

Author

Surtaev, A.S., Pavlenko, A.N., Kuznetsov, D.V., Kalita, V.I., Komlev, D.I., Ivannikov, A. Yu., and Radyuk, A.A.

Subjects

*HEAT transfer coefficient, *POROUS materials, *EBULLITION, *LIQUID nitrogen, *SURFACE coatings, *PLASMA spraying

Abstract

The results of experimental study of heat transfer and crisis phenomena at pool boiling of liquid nitrogen with different heating conditions on the surface with capillary-porous coating are presented. Porous coatings with different thicknesses (400 and 1390 μm), morphology and high porosity (up to 80%) were obtained using the new plasma spraying technique. It was shown that at steady-state heat release the heat transfer at boiling essentially depends on the thickness and morphology of the coating. The maximum enhancement (∼300%) compared to the smooth heater was detected to coated heater with a thickness of 1390 μm at low heat fluxes. The mechanism of heat transfer enhancement at pool boiling by using the capillary-porous coatings was proposed. Heat transfer hysteresis was detected for the heater with the coating of 400 μm. For the smooth heaters and the heater with 1390 μm coating, the heat transfer coefficients almost coincide with an increase in the heat flux and with its decrease. Data on the effect of coatings with different thicknesses on the critical heat flux (CHF) at boiling under steady-state heat release are presented. It is shown that for the smooth heaters the value of critical heat flux at rapid heating decreases in comparison with steady-state heat release. Capillary-porous coatings have a significant influence on development of the transition process and crisis phenomena at stepwise heat release. There is degeneration of boiling crisis development at rapid heating on the coated surfaces at the heat fluxes below the value of the CHF at steady state heat release. Fast transition to film boiling at stepwise heat release on the coated heaters with different thicknesses is observed at the heat fluxes 2 times higher than the critical heat fluxes, obtained at steady state heating. [ABSTRACT FROM AUTHOR]

Published

2017

47. Mechanism of graphitization and optical degradation of CVD diamond films by rapid heating treatment.

Author

Yan, Xiongbo, Wei, Junjun, Guo, Jianchao, Hua, Chenyi, Liu, Jinlong, Chen, Liangxian, Hei, Lifu, and Li, Chengming

Subjects

*GRAPHITIZATION, *CHEMICAL vapor deposition, *DIAMOND films, *POLYCRYSTALS, *X-ray diffraction

Abstract

Polycrystalline CVD free-standing diamond films have been heat treated through a rapid heating process using a direct current (DC) arc plasma jet system within the temperature range of 1500–2000 °C. The optical transmission of the diamond film decreases when the treatment temperature exceeds 1500 °C. When the diamond film was annealed to 1800 °C for just 1 min, the infrared (IR) transmittance at λ = 10.6 μm of the film was significantly decreased from 60.5% to 4.0%, due to the transformation from diamond to graphite. Further increase of the temperature to 2000 °C leads to complete loss of optical transmittance in only 30 s, due to the detrimental occurrence of graphitization. XRD patterns indicate that graphite ultimately grows preferentially along the (0002) plane by forming disordered or turbostratic graphite as intermediate product. Raman spectra and SEM images verify that at 1500–1850 °C graphitic carbon transforms from the diamond surface in the form of protruding submicron crystallites, which were still containing a number of sp 3 C C bonds. In addition to graphitization on the external surface, the diamond-graphite phase transition also occurs along the grain boundaries and the calculated activation energy of the grain boundary graphitization process is 276 kJ·mol − 1 for the CVD diamond. [ABSTRACT FROM AUTHOR]

Published

2017

48. Local out-of-plane deformation of CFRP ablator subjected to rapid heating.

Author

Koyanagi, Jun, Fukuda, Yasuhiro, Yoneyama, Satoru, Hirai, Ken-ichi, Yoshimura, Akinori, Aoki, Takuya, and Ogasawara, Toshio

Subjects

*CARBON fiber-reinforced plastics, *DEFORMATIONS (Mechanics), *ABLATIVE materials, *THREE-dimensional imaging, *PYROLYSIS

Abstract

This study investigates local out-of-plane deformation of a carbon fiber reinforced phenolic polymer ablator subjected to very rapid heating. Local out-of-plane deformation was measured using a three-dimensional digital image correlation technique at high temperatures. This was achieved by attaching high temperature resistant random patterns on the specimen surface using a ceramic bond. Additionally, blue filters intended for cutting strong infrared radiation from the specimen were also used. This study then discusses the mechanisms of the local out-of-plane deformation under rapid heating conditions in terms of carbonization, pyrolysis gas occurrence, gas pressure storage, and interlaminar debonding due to gas pressure. [ABSTRACT FROM PUBLISHER]

Published

2017

49. A finite element formulation for thermally induced vibrations of functionally graded material sandwich plates and shell panels.

Author

Pandey, Shashank and Pradyumna, S.

Subjects

*FUNCTIONALLY gradient materials, *VIBRATION (Mechanics), *FINITE element method, *STRUCTURAL plates, *STRUCTURAL shells

Abstract

A finite element formulation based on a higher-order layerwise theory is presented for the first time to investigate thermally induced vibrations of functionally graded material (FGM) sandwich plates and shell panels. The properties of FGM sandwich are assumed to be position and temperature dependent. The upper and lower layers of the sandwich panel are considered to be made of pure ceramic and metal, respectively and the elastic properties of FGM core are varied according to a power-law function. The top surface is exposed to a thermal shock and the bottom surface of the panel is either kept at a reference temperature or thermally insulated. The one-dimensional transient heat conduction equation is solved using a central difference scheme in conjunction with the Crank-Nicolson method. A higher-order layerwise theory is used for FGM sandwich panels, in which a higher-order displacement field for the FGM core and a first-order displacement field for the facesheets are assumed. The governing equations are solved using Newmark average acceleration method. It is shown that the proposed layerwise finite element formulation is simple and can easily be applied to investigate FGM sandwich plates and shell panels subjected to rapid heating. [ABSTRACT FROM AUTHOR]

Published

2017

50. Nucleation and bubble growth during puffing and micro-explosions in composite droplets.

Author

Bar-Kohany, Tali, Antonov, Dmitrii V., Strizhak, Pavel A., and Sazhin, Sergei S.

Subjects

*DISCONTINUOUS precipitation, *BUBBLES, *HOMOGENEOUS nucleation, *RATE of nucleation, *HETEROGENOUS nucleation, *NATURAL heat convection

Abstract

• Breakup time of droplets is evaluated as the sum of heating and bubble growth times. • Heterogeneous nucleation temperature depends on the heating rate and is often lower than the homogeneous nucleation temperature. • Smaller droplets lead to both shorter heating and bubble growth times. • Higher ambient temperature lead to longer heating times yet shorter bubble growth times. • Heating time is dominant over the bubble growth duration throughout the entire domain, under conductive or natural convection conditions. • For micron-sized droplets, puffing and micro-explosions are prone to occur during the inertial bubble growth regime. Heating of droplets composed of water and fuel is known to lead to internal nucleation and bubble growth that can eventually lead to their puffing and to micro-explosions. The time to puffing/micro-explosions includes times spent on: heating (time to nucleation P l e a s e s t r i k e t h e S y m b o l t _ N f r o m t h e a b s t r a c t), bubble growth P l e a s e s t r i k e : t gr f r o m t h e a b s t r a c t. In the present paper, we examine the effect of different aspects of bubble growth on the puffing and micro-explosions. Specifically, we address the effects of nucleation temperature and the relative positions of the inner water sub-droplet and the bubble within it. The nucleation temperature of the water sub-droplet is higher than its normal boiling temperature yet lower than its spinodal temperature in most realistic cases. The degree of superheating and the nucleation time depend on the heating rate and the nucleation site density. Higher nucleation temperatures imply larger driving force for the bubble growth. Bubble growth rate is dominated by the degree of superheating, while growth time is dominated by both the degree of superheating and the location of the bubble with respect to the inner and outer interfaces of the composite droplet. It is found that the inertial bubble growth regime is dominant for micron-sized droplets, and thus sensitivity to the modelling of the inertial regime can be of crucial importance to the evaluation of the breakup time for the droplets. The model for puffing and micro-explosion presented in the paper considers an isolated bubble growing at the water/fuel interface at various degrees of superheating, and for a wide range of Jakob numbers. This analysis allows us to assess the sensitivity of bubble growth time to the initial bubble location, and to generalise the previously developed model of the phenomenon taking into account the effect of finite time of bubble growth during the development of puffing/micro-explosion. [ABSTRACT FROM AUTHOR]

Published

2023