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2. Comment on the paper "Joule heating and viscous dissipation in flow of nanomaterial by a rotating disk, Tasawar Hayat, Muhammad Ijaz Khan, Ahmed Alsaedi, Muhammad Imran Khan, International Communications in Heat and Mass Transfer, 89(2017) 190–197".
- Author
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Pantokratoras, Asterios
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ROTATING disks , *VISCOUS flow , *MASS transfer , *INTERNATIONAL communication , *HEAT transfer - Abstract
Abstract The present comment concerns some doubtful results included in the above paper. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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3. Comment on the paper "Activation energy impact in nonlinear radiative stagnation point flow of Cross nanofluid, Muhammad Ijaz Khan, Tasawar Hayat, Muhammad Imran Khan, Ahmed Alsaedi, International Communications in Heat and Mass Transfer 91, 2018, 216–224"
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Pantokratoras, Asterios
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STAGNATION point , *MASS transfer , *ACTIVATION energy , *INTERNATIONAL communication , *STAGNATION flow , *HEAT transfer - Abstract
Two mistakes exist in [1]. [ABSTRACT FROM AUTHOR]
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- 2020
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4. An experimental investigation on oscillating heat pipe under trans-critical conditions.
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Ji, Yulong, Li, Yadong, Xu, Fengyang, Yu, Chunrong, and Liu, Huaqiang
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HEAT pipes , *HEAT transfer , *THERMAL resistance , *CRITICAL temperature , *WORKING fluids , *ELECTRONIC equipment - Abstract
With the highly integrated development of electronic components, higher requirements are put forward for heat transfer components, there is an urgent need for high-performance heat transfer components. Oscillating heat pipe (OHP) is novel types of heat pipe with excellent heat transfer capability. However, the heat transfer limit hinders their operation and application. This paper proposes an OHP under trans-critical conditions with the working fluid of R218 and explores its operating characteristics and heat transfer capability. Visualization experiments and pressure monitoring were conducted to analyze the state changes within the OHP under trans-critical conditions. After evaporation section temperature surpassing the critical temperature of R218, the pressure increases with the temperature, once the pressure reached near the critical pressure, OHP can transcend the limitation of the critical temperature and realize efficient oscillating operation under trans-critical conditions. With stable operation, the working fluid velocity can reach up to 1.49 m/s, and the OHP under trans-critical conditions presented excellent heat transfer performance with the thermal resistance of 0.22 °C/W. This paper proves the feasibility of the OHP under trans-critical conditions and provides a basis for further research. [ABSTRACT FROM AUTHOR]
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- 2024
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5. Research on performance of micro gas turbine recuperator: A review.
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Wang, Ruihao, Wang, Yanhua, Chen, Xiaohu, Wang, Meng, and Wang, Zhongyi
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RECUPERATORS , *THERMODYNAMICS , *GAS turbines , *MACHINE performance , *POWER resources , *HEAT transfer - Abstract
The distributed energy supply system provides a good scheme for energy supply. The micro gas turbine with a recuperator is a common power device in distributed energy supply systems. In recent years, several achievements have been made in the development of micro gas turbine recuperators. Plate-fin and primary surface recuperators have been used in mature applications. Moreover, the thermodynamic properties of the heat transfer channel have been studied in detail. Among them, the cross wavy primary surface recuperator developed by Capston Company is one of the important achievements. This paper reviews the technical development of thermodynamic performance of micro gas turbine recuperator in recent years. The micro gas turbine recuperators are divided into plate-fin and primary surface recuperators commonly. In this paper, the correlation formula, heat exchange enhancement, optimum design and the influence of recuperator on the overall machine performance are reviewed. It has been found that the plate-fin recuperators have been sufficiently studied by scholars, and the results are more comprehensive. As for the primary surface recuperators, which have just become popular in recent years, the research results are less comprehensive due to their unique structure. In the future development of micro gas turbine recuperators, this will be the future research and development trend due to the high heat exchange efficiency and the lack of comprehensive research on primary surface recuperators. [ABSTRACT FROM AUTHOR]
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- 2024
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6. Enhancement and optimization of cryogenic metal tube chilldown heat transfer using thin-film coating, II. Chilldown efficiency, flow direction and tube wall thickness.
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Wang, Hao, Huang, Bohan, Dong, Jun, Chung, J.N., and Hartwig, J.W.
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LIQUID nitrogen , *HEAT transfer , *TUBES , *REYNOLDS number , *SURFACE conductivity , *SURFACE coatings , *THERMAL efficiency - Abstract
This paper is the second of a two-part series that presents experimental data and analysis on the liquid nitrogen quenching heat transfer process of a stainless-steel tube with an inner surface low-thermal conductivity thin-film coating. This paper focuses on the effects of different flow directions and two tube wall thicknesses. Additionally, this paper also provides an analysis on the chilldown thermal efficiency of the quenching process. Three flow directions with four different inner surface coating modifications, and three tube wall thicknesses were examined. The experimental data covers the Reynolds numbers ranging from 3500 to 140,000. The chilldown efficiency, along with chilldown time and LN 2 (liquid nitrogen) mass consumption were analyzed to assess the overall performance of the LN 2 line chilldown process. For thin tube wall cases, the chilldown efficiencies cover a range between 3% and 41%, and the maximum chilldown efficiency value is found for the tube with 3 L coating at Re = 5278 in the vertical up flow direction. For thick wall tube cases, the efficiencies cover a range between 4% and 52%, and the maximum chilldown efficiency value was found for the tube with 4 L coating at Re = 5308 in the vertical up flow direction. [ABSTRACT FROM AUTHOR]
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- 2024
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7. Towards enhanced heat and mass exchange in adsorption systems: The role of AutoML and fluidized bed innovations.
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Krzywanski, Jaroslaw, Skrobek, Dorian, Sosnowski, Marcin, Ashraf, Waqar Muhammad, Grabowska, Karolina, Zylka, Anna, Kulakowska, Anna, Nowak, Wojciech, Sztekler, Karol, and Shahzad, Muhammad Wakil
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ION exchange (Chemistry) , *ENERGY development , *HEAT transfer , *HEAT recovery , *DESIGN techniques - Abstract
The selection of optimal design and the most efficient operational parameters for energy devices constitute a priority task for sustainable development and increasing energy efficiency within the net-zero emissions strategy. This is particularly important in adsorption cooling and desalination systems with poor performance due to unfavourable heat transfer conditions in conventional packed beds of adsorption chillers (ACs). Therefore, looking for additional ways of performance improvement is still challenging, especially covering different design variants and operational strategies. The existing complex, time-consuming and costly analytical, numerical and experimental methods, usually focused on a specific design and operating parameters of conventional packed adsorption beds, cannot tackle these comprehensive problems. Since artificial intelligence (AI) based models are considered tools that sometimes may overcome the shortcomings of the programmed computing approach and the experimental procedures, the paper introduces automated machine learning (AutoML) as a general approach for the design and optimization study of adsorption cooling and desalination systems. The double-effect, i.e. specific cooling capacity (SCP) and specific daily water production (SDWP) of various adsorption chillers (ACs) operating in large-, pilot- and small-scale adsorption cooling and desalination systems, is considered in the study. The paper also presents a novel big data optimization procedure for selecting the best operating and design strategy in adsorption cooling and desalination technology. Finally, a new concept of fluidized bed-type application in adsorption chillers is proposed, which allows for enhancing the performance of ACs. The presented approach can be referred to as a complementary design technique in adsorption cooling and desalination systems, besides the existing complex analytical and time-consuming numerical methods and expensive experiments. • Double-effect desalination and cooling production in adsorption chillers (AC) are evaluated • The new approach allows considering various cooling and desalination adsorption systems. • The novel concept of fluidized bed application in adsorption systems is proposed. • The developed models constitute powerful tools for optimizing ACs systems' performance. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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8. Effect of surface structure on fluid flow and heat transfer in cold and hot wall nanochannels.
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Qin, Shiyi, Chen, Zhanxiu, Wang, Qing, Li, Wenguang, and Xing, Hewei
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HEAT transfer fluids , *LIQUID-liquid interfaces , *SURFACE structure , *HEAT convection , *NANOFLUIDICS , *FLUID flow - Abstract
Nanochannels consisting of hot and cold walls with periodic rectangular and triangular nanostructures were simulated by molecular dynamics in this paper, the periodic size dimensionless parameters φ was defined to describe the dimension of nanostructures on the wall. The results show that the addition of nanostructures leads to the variation of mass density distribution of fluid near the wall. A hot wall with nanostructures can promote the appearance of a fluid high-potential area near it. The discrepant attraction for fluid from the wall caused by the different wall conditions leads to different flow characteristics in nanochannels. Fluid velocity growth rate near the hot wall is 10.5% higher than that near the cold wall. Average velocity of the fluid near the hot wall is 5.1% higher than that of fluid near the cold wall. A wall with rectangular nanostructures at φ = 0.28 shows minimum flow resistance among rough hot walls, while a wall with triangular nanostructures at φ = 0.14 has minimum flow resistance among rough cold walls. Heat is transferred from the hot wall to the cold wall through fluid flow. Wall conditions impact the heat transfer situation of fluid in flow boundary by changing the fluid mass density contribution. The addition of nanostructures and decrease of nanostructures size is beneficial for heat transfer while unfavorable for fluid flow, convective heat transfer was influenced by their combination. For a wall with 300 K, the addition of rectangular nanostructures at φ = 0.07 has the best convective heat transfer performance. For a wall with 200 K temperature, increasing triangular nanostructures at φ = 0.14 on the wall can reach the best convective heat transfer capacity. This paper can provide a theoretical foundation for the optimization of nanochannels to achieve best convective heat transfer ability. [ABSTRACT FROM AUTHOR]
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- 2024
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9. An overview of the magnetic field effect on heat transfer and entropy generation in cavities: Application of the second law of thermodynamics and artificial intelligence.
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Bayareh, Morteza and Baghoolizadeh, Mohammadreza
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MAGNETIC field effects , *NANOFLUIDICS , *SECOND law of thermodynamics , *HEAT transfer , *HEAT convection , *ARTIFICIAL intelligence , *ENTROPY - Abstract
The presence of magnetic field results in a reduction in natural convective heat transfer and entropy generation in cavities. The use of nanofluids improves the performance of thermal systems. The present paper discusses the impact of uniform and non-uniform magnetic fields on the second-law performance of nanofluid-filled and porous cavities, introduces artificial intelligence (AI) approaches, and examines the applications of AI in optimizing heat transfer and entropy generated in these systems. The mathematical formulation is presented in terms of the entropy generation for natural convection in cavities. This paper demonstrates the influences of various important non-dimensional parameters on entropy generation in cavities. Besides, advances in the second-law performance of cavities and the role of AI techniques in the field are discussed and future directions are provided. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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10. Optimization of thermohydraulic performance of tube heat exchanger with L twisted tape.
- Author
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Shijie, Li, Zuoqin, Qian, and Qiang, Wang
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HEAT exchangers , *CENTRIFUGAL force , *NUSSELT number , *HEAT transfer , *TUBES , *HEAT transfer fluids , *ADHESIVE tape , *VORTEX generators , *THERMAL hydraulics - Abstract
A numerical investigation was conducted to explore the heat transfer optimization effect of circular tube heat exchanger with L-shaped twisted tape insert and to find the optimal parameter design in this paper. For better thermohydraulic performance, the effects of twist pitch (P), inner diameter (D), tape width (W) and number of tape (N) were studied with Reynolds number ranged from 1875 to 3750. Moreover, response surface method (RSM) was employed to indicate the relationship between the Nusselt number (Nu) and these parameters. With the analysis of flow structure inside the tube, it was conducted that the twisted tape insert was helpful to transform the axial velocity of fluid to radial velocity, forming vortex in the L region. The numerical results showed that the Nu and friction factor (f) of the tube fitted with L-shaped twisted tape insert gained an 199% to 208% increase and 674% to 696% when compared with that of smooth tube respectively. Besides, an optimal parameters set was obtained with P = 65.59 mm, W = 0.95 mm, D = 8.80 mm, in which the Nu and f were increased by 204% and 704% respectively as the results of response surface method. • Effects of L-shaped twisted tapes insert on heat transfer and flow characteristics in were numerically investigated. • The influence of four geometric parameters of twisted tape insert on thermos-hydraulic performance were studied. • The enhanced thermal performance of the L-shaped twisted tapes was obtained by centrifugal force. • The effect of short side of the L-shaped on the thermal performance and flow characteristics were discussed. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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11. Effect of the heat flow distribution and thermophysical properties of the pipe wall and fluid on the wall temperature response to a rising Taylor bubble.
- Author
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Guo, Wei, He, Xiufen, Kong, Fulin, Shen, Minghai, Chen, Biduan, Tong, Lige, Jia, Chao, Li, Yanhui, Liu, Chuanping, and Wang, Li
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THERMOPHYSICAL properties , *DIFFUSION measurements , *HEAT transfer fluids , *SPECIFIC heat , *PROPERTIES of fluids , *TEMPERATURE , *THERMAL conductivity - Abstract
A novel non-intrusive thermal diffusion measurement (TDM) method has been proposed for measuring the phase flowrates of gas–liquid slug flows in our previous research. Since the structure of TDM was arbitrarily designed and needed to be optimized for accurate measurement, the effect of the heat flow distribution and the thermophysical properties of the pipe wall and fluid on the wall temperature response to a rising Taylor bubble (TB) is further investigated by using the CFD tool in this paper. The wall temperature and temperature rise are used to describe the wall temperature response, and their variation rules with heat flow distribution and the thermophysical properties of the pipe wall and fluid are presented and analyzed based on heat transfer. The simulation results indicate that the optimal heating length for a large wall temperature rise and small power consumption is 0.6 D , and the optimal pipe material should be with small density and specific heat and a suitable thermal conductivity of about 15 W/(m·K). Moreover, the wall temperature response is obvious, especially for TBs moving in the liquid with large fluid thermal conductivity, density, and specific heat, and small viscosity. The paper can clarify the wall temperature response mechanism of the heated pipe wall and provide a theoretical basis for the development of the TDM method. • Local instantaneous heat transfer characteristics of a rising TB are investigated. • Wall temperature responses under different heat flow distributions are presented. • Effect of wall/fluid thermophysical properties on temperature response is analyzed. • Titanium is the optimal metal for strong temperature response in the TDM method. • Optimal heating width is 0.6 D for strong response and energy saving. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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12. Experimental investigation on the interaction characteristics of lead‑bismuth liquid metal and water.
- Author
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Zhang, Lin, Deng, Chang, and Liu, Xiaojing
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LIQUID metals , *BISMUTH , *ENERGY conversion , *ENERGY consumption , *HEAT transfer , *FAST reactors , *METALLURGY , *NUCLEAR energy - Abstract
The energy conversion and utilization of liquid metals is becoming one of the effective ways to solve energy problems. The conversion and transfer of thermal energy from liquid metals to water are significant in advanced nuclear energy and metallurgy. It has been an urgent concern, especially in Generation IV of advanced nuclear energy systems‑lead-cooled fast reactors and the ultimate energy source for humanity-fusion engineering. In this paper, a large-scale liquid metal and water interaction test platform was developed to investigate the lead‑bismuth liquid metal and water interaction and the cover gas pressurization characteristics. Firstly, the evolution of phase behavior and water/vapor migration paths were inferred based on the transient temperature law. Secondly, the cover gas pressurization patterns above the molten pool were analyzed, and the test data showed three pressurization patterns, including two types of local vapor explosions. Additionally, this paper predicted the existence of another dangerous pressurization mode, i.e., overall vapor explosion. Finally, the cover gas pressurization rate model was established, and there is an appropriate matching between the model and test data with an average relative error of 12.6%. This paper provides an essential reference for profoundly understanding the energy conversion and thermal interactions between liquid metals and water. • A large-scale liquid metal and water interaction test platform was developed to investigate energy conversion and interaction. • Based on the transient temperature law, we discovered the gas-phase evolution characteristics during lead-water interaction. • Three different types of pressurization patterns of cover gas were identified. • A model of cover gas pressurization was developed to predict the pressurization rate. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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13. Effects of coupling of groove microstructure and mixed wettability on flow boiling heat transfer enhancement of R134a in microchannels.
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Zhang, Wenjie, Yue, Linfei, Qi, Cong, Wang, Yuwei, Wang, Huanguang, and Liang, Lin
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EBULLITION , *HEAT transfer , *HEAT transfer coefficient , *WETTING , *HYDROPHOBIC surfaces , *MICROSTRUCTURE , *HEAT pipes - Abstract
Mixing of surface microstructure and wettability is one of the future development trends. Their combination always affects the bubble motion and heat transfer coefficient under pool boiling/flow boiling, but it is difficult to distinguish their respective contributions. This work studies the combination of new microstructure and mixed wettability to improve the flow boiling heat transfer in the channel. The nucleation, growth, coalescence and departure behaviors of R134a boiling bubbles were numerically analyzed. Effects of different heights, gaps and mixed wettability of microstructures and heat fluxes on bubble emission frequency and boiling heat transfer coefficient were discussed. Results showed that this new microstructure provides the bubble with the momentum of lateral motion, which helps the bubble to merge and leave faster. The surface of the hydrophobic groove coupled with the hydrophilicity as the substrate can effectively increase the bubble emission frequency, up to 134.37%. At the same time, the heat transfer coefficient decreases with the increase of the height of the microstructure, and it also increases with the increase of the microstructure gap. Finally, the contribution of each variable was determined by analysis of variance. The research results in this paper provide a reference for heat pipe and vapor chamber. • A creative microchannels with mixed wettability was proposed and optimized. • Synergistic effect of groove microstructure and mixed wettability was studied. • Surface mixed wettability has more influence on boiling heat transfer. • Bubble emission frequency of surface-A is 134.37% higher than surface-B. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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14. A general ray tracing approach for solving thermal radiation in regular one-dimensional variable index media via the Monte Carlo method.
- Author
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Sarvari, S.M. Hosseini
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MONTE Carlo method , *RAY tracing , *RAY tracing algorithms , *HEAT radiation & absorption , *HEAT transfer , *THERMOPHYSICAL properties - Abstract
In the heat transfer community, one-dimensional media refers to some media where the temperature and other thermophysical properties vary along one direction. Plane-parallel, concentric cylindrical, and concentric spherical geometries are among of regular one-dimensional media. In this paper, a general ray tracing approach is presented to track the curve paths of energy particles in regular one-dimensional variable index media. The domain of interest is limited by specular sidewalls and the medium is divided into slices with constant temperature and radiative properties. Then, the path of random energy particles emitted from boundary surfaces and volume elements are traced, element by element, until they absorb by diffuse-gray surfaces or the gray medium. After counting the number of absorbed particles by each boundary surface and volume element, the Monte Carlo method is performed to simulate thermal radiation heat transfer. The results are presented for three regular geometries, including plane-parallel, concentric cylindrical, and concentric spherical media, and the effects of radiative properties are investigated by some numerical experiments. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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15. Numerical and experimental investigation of heat transfer in the spiral coiled tubes: Correlation development for Nusselt number and friction coefficient calculation.
- Author
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Farhadi, Sobhan, Shekari, Younes, and Ansari, Hamid
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NUSSELT number , *HEAT transfer , *HEAT recovery , *HEAT exchangers , *PRESSURE drop (Fluid dynamics) , *COMPUTATIONAL fluid dynamics , *TUBES - Abstract
In this paper, we present a comprehensive study on the heat transfer in the spiral coiled tubes, employing both numerical simulations and experimental analysis. The investigation includes an exploration of water flow at different mass flow rates, ranging from 0.025 to 0.11 kg / s , to capture a wide range of operating conditions. The numerical simulations were conducted using advanced computational fluid dynamics (CFD) techniques, providing detailed insights into the heat transfer behavior within the spiral tube. Concurrently, experimental tests were performed to validate the numerical results and compare them with existing findings from previous studies. The primary aim of our study is to establish correlations for calculating the Nusselt number and friction coefficient in the spiral coiled tubes. These correlations serve as essential tools for engineers and researchers in predicting heat transfer characteristics and pressure drop, thus facilitating the design and optimization of heat exchangers and heat recovery systems that incorporate spiral coiled tubes. Overall, the results obtained from this investigation enhance our understanding of heat transfer in spiral tubes and contribute to the development of reliable predictive models. The proposed correlations offer practical and efficient means of assessing heat transfer performance, making significant strides towards achieving more energy-efficient and sustainable industrial processes. • Fluid flow and heat transfer in a spiral coiled tube were studied. • Effects of mass flow rate of water on heat transfer in a spiral coiled tube were investigated. • Correlations for calculation of Nusselt number and friction coefficient for water flow in a spiral coiled tube were developed. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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16. Investigation of the impact of the spray cooling process using various spray nozzles on the unevenness of energy transfer from the metal surface.
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Cebo-Rudnicka, Agnieszka, Hadała, Beata, Szajding, Artur, and Jasiewicz, Elżbieta
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SPRAY nozzles , *ENERGY transfer , *METALLIC surfaces , *HEAT flux , *HEAT transfer - Abstract
Cooling systems often rely on numerical calculations with precise heat transfer boundary conditions (HTBC), usually expressed as average values. The value of the average HTBC depends on the area in which they are determined. The paper presents a new approach showing the influence of the choice of the method of supplying liquid onto the surface on the non-uniformity of energy transfer from the cooled surface, which is important in the selection of the determination domain on the HTBC. The tests were carried out for two full-cone nozzles with different spray angles and two materials with different thermal properties. The local and average heat fluxes were determined for various distances of the nozzles from the surface and various liquid supply pressures. Cooling capacity, unevenness of energy transfer from the surface and quenching characteristics were evaluated and assessed using cooling curves. The study concludes that adopting HTBC based on average heat flux variation does not cause a significant error in the assessment of energy transfer during cooling with a nozzle with spray angle of 60° for EN 1.4845 steel. However, for Inconel and a nozzle with spray angle of 45°, the noticeable non-uniformity requires the application of a local HTBC. • Unevenness the spray cooling process. • Possibilities of using the average heat transfer boundary condition. • Recommendations for the use of local heat transfer boundary condition. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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17. An experimental study on the spreading characteristics and burning behaviors of continuous spill fires under cross flow.
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Ma, Hanchao, Zhao, Jinlong, Huang, Hong, Zhang, Jianping, and Wang, Zhenhua
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WIND speed , *DRAG force , *TUNNEL ventilation , *LIQUID fuels , *WIND pressure , *HEAT transfer - Abstract
Fuel leakage and spill fires often occur during storage and transportation of liquid fuels. And the spread and burning processes of spill fires are susceptible to cross-air flows. In this paper, spill fire experiments were conducted on a fireproof glass (with or without ignition) under different wind speeds (0–2 m/s). The effects of wind on the spread process and burning behaviors were analyzed. Results showed that, for the cases without ignition, the spread length could vary in a non-linear manner with wind speed. And a spread length model was developed based on force analysis. For spill fires under small wind speeds, the burning area increased firstly, followed by a decrease before stabilization. When the wind speed exceeded a critical value, the fuel layer spread rapidly in the upwind direction after the shrinking phase. The steady stage was observed for all tests. With the wind speed increase, the quasi-steady burning area changes from being circular to elliptic first, before it gradually became circular in the end. To explain this process, a detailed heat transfer analysis was conducted. Considering the fuel layer shape and the heat transfer characteristics of spill fires, an analytical burning rate model was developed. • Wind drag force shows a significant effect on the spreading process for non-ignition continuous leakage tests. • Three typical spill fire spreading behaviors can be observed under different wind speeds. • The variation of the convective feedback with wind speed is primarily responsible for the change in the fuel layer shape. • An analytical model is developed based on the stagnant layer theory to calculate the burning rate of liquid fires. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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18. Research on topology optimization of liquid-cooled plates based on multi-level optimization.
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Xie, Liyao, He, Zhaowei, Zhao, Yulong, Vulin, Domagoj, and Bhayo, Barkat Ali
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IRON & steel plates , *THERMAL resistance , *PRESSURE drop (Fluid dynamics) , *TOPOLOGY , *HEAT transfer , *MATHEMATICAL optimization - Abstract
This paper employs topology optimization techniques to enhance the performance of liquid-cooled plates while investigating the optimization process and its outcomes. A multilevel optimization strategy is implemented to refine the accuracy and smoothness of the optimization process. The study demonstrates that expanding the range of penalty factors and refining the granularity of penalty factors can effectively enhance the capability of multilevel optimization in suppressing the formation of intermediate densities. Furthermore, a multi-objective function is utilized to strike a balance between the heat transfer efficiency and the hydraulic performance of the liquid-cooled plate. Ultimately, after considering aspects related to heat transfer and hydraulic performance, the research finds that compared to traditional straight-channel liquid-cooled plates, liquid-cooled plates featuring streamlined multi-branched flow channels not only increase the heat transfer area but also reduce pressure drop. As a result, this design improves the temperature uniformity of the liquid-cooled plate and enhances the velocity uniformity of the cooling fluid. At different inlet velocities, the topology-optimized liquid-cooled plate exhibits a reduction in both effective thermal resistance and pumping power compared to the traditional straight-channel liquid-cooled plate. • Multi-level optimization strategy improves the smoothness and precision of the topology optimization process. • Expanding the penalty factor range and refining granularity helps to reduce the intermediate density in the topology process. • Topology-optimized liquid-cooled plates improves the uniformity of coolant velocity and temperature distribution. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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19. Heat transfer enhancement for porous microchannel heat sinks by optimizing wall heat flux distribution.
- Author
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Li, Xin, Wang, Jiabing, and Yang, Kun
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HEAT flux , *HEAT sinks , *THERMAL resistance , *NUSSELT number , *PRANDTL number , *HEAT pipes , *HEAT transfer , *FINS (Engineering) - Abstract
The porous microchannel heat sink can be used to meet the increasing demand for electronic device cooling. In this paper, heat transfer is enhanced by optimizing heat flux distribution for porous microchannel heat sinks subject to an exponential heat flux. The Nusselt number, dimensionless wall temperature and thermal resistance are obtained using the semi-analytical method. The Nusselt number is found to be dependent on the product of dimensionless exponent, Reynold number, and Prandtl number. The optimal heat flux distribution is dependent on the length of the channel and it is that under constant wall temperature boundary condition in most cases. The thermal performance is assessed using the thermal resistance ratio between constant wall temperature and constant heat flux boundary conditions. An optimal length exists when the constant wall temperature condition is used to reduce the maximum wall temperature. The effects of Biot number and the ratio between effective thermal conductivities of solid and fluid phases on the minimum value of the thermal resistance ratio and the optimal length are also studied. The result shows that the thermal resistance can be reduced by about 28% by optimizing the heat flux distribution, compared with the commonly used constant heat flux boundary condition. • Heat transfer for porous heat sinks is enhanced by optimizing wall heat flux. • The optimal heat flux distribution is that for CWT conditions in most cases. • An optimal length is found when the constant temperature conditions is used. • The thermal resistance can be reduced by about 28%. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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20. A fast Bayesian parallel solution framework for large-scale parameter estimation of 3D inverse heat transfer problems.
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Wang, Chen, Heng, Yi, Luo, Jiu, and Wang, Xiaoqiang
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HEAT transfer , *PARAMETER estimation , *HEAT flux , *INVERSE problems , *GIBBS sampling - Abstract
The inverse heat transfer problems (IHTP) have a wide range of applications in the engineering field. Bayesian methods using Markov Chain Monte Carlo (MCMC) have long been considered as a robust and effective method for solving inverse problems. However, the discretization of the problem domain by the spatio-temporal Galerkin skill, i.e., the finite element interpolation also includes the time dimension, making the scale of the unknown parameters extremely difficult for Bayesian calculations. In this paper, a fast Bayesian parallel sampling (FBPS) framework is proposed for large-scale parameter estimation of benchmark three-dimensional inverse heat transfer problems (3D-IHTP). The FBPS we developed achieves a parameter computation scale of 10 5 magnitude within minutes, through dimensionality reduction of the space-time dependent problem domain. The Hamiltonian Monte Carlo (HMC) sampler, which is proven to be more efficient for high-dimensional parameter estimation, is employed. Through several simulation tests of IHTP, it was confirmed that the solving efficiency of FBPS surpasses that of the traditional Bayesian strategy significantly. Finally, FBPS is successfully developed to estimate the unknown heat flux on the chip heat sink and pack interface effectively, given some simulated high resolution measurement data. The reliability and efficiency show that FBPS has the potential to support efficient prediction techniques for a class of IHTPs in engineering applications. • A fast Bayesian parallel sampling framework (FBPS) for 3D-IHTP is proposed. • Computation time to solve IHTP with unknown size of 105 is in minute level. • FBPS is about 55 times faster than the traditional Gibbs method. • FBPS provides reliable technical idea to solving large-scale Bayesian inverse problem. • FBPS is applied to the inverse problem of chip packaging heat dissipation. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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21. Effect of vertical vibration on transient heat transfer characteristics of flow boiling in small rectangular channels.
- Author
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Shao, Wen-Bin, Zhou, Yun-Long, and Hu, Zhong-Yuan
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HEAT transfer , *HEAT transfer coefficient , *THERMAL boundary layer , *FUEL cell vehicles , *EBULLITION - Abstract
In the thermal management of fuel cell vehicles, radiators are subjected to vibrations due to vehicle speed and road surface irregularities. However, there has been no comprehensive study of the impact of these vibrations on the heat transfer performance of radiators. Therefore, this paper employs R141b to conduct three-dimensional transient numerical simulations of flow boiling in small channels under vertical vibrations. The study reveals that the single-phase heat transfer coefficient exhibits periodic variations. At the same vibration frequency, the heat transfer frequency for the vertically oriented heating surface is twice that of the horizontally oriented surface, This is because the thermal boundary layer varies with the vibration velocity. Furthermore, as the frequency increases to 21 Hz, the time-averaged heat transfer coefficient can increase by up to 2.5 times. Following boiling onset, for horizontally oriented heating surfaces, an increase in frequency or amplitude enhances the transient heat transfer performance. Under the conditions of 28 Hz and 5 mm, the heat transfer coefficient can increase by 125.7%. However, for vertically oriented heating surfaces, when the frequency exceeds 14 Hz or the amplitude exceeds 8 mm, the heat transfer performance weakens after 7.143 s due to the promotion of bubble coalescence by the vibrations. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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22. Experimental studies on thermal conductivity and heat transfer of 1-Butyl-3-methylimidazolium tetrafluoroborate ionic liquid and its nanocolloids.
- Author
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Minea, Alina Adriana and Cherecheş, Elena Ionela
- Subjects
- *
THERMAL conductivity , *THERMAL diffusivity , *HEAT transfer , *IONIC liquids , *TETRAFLUOROBORATES , *ALUMINUM oxide , *PRANDTL number - Abstract
This paper outlines and discusses the thermal conductivity of 1-Butyl-3-methylimidazolium tetrafluoroborate ionic liquid, as well as three classes of nanocolloids. The [C4mim][BF4] ionic liquid was enhanced with three kinds of nanoparticles, Al 2 O 3 , ZnO and MWCNT and all fluids thermal conductivity was experimentally measured. Results discussion includes also an in-depth analysis on Prandtl number and thermal diffusivity. All the data were carefully debated in terms of state of the art advancement and these suspensions suitability for practical applications in heat transfer. It was found that the thermal conductivity increases with nanoparticles addition and this enhancement depends on nanoparticle type and temperature. Plus, the temperature influence is rather limited, while the consideration on Prandtl number and thermal diffusivity revealed that it is extremely relevant to consider all the thermophysical properties when choosing a new thermal fluid. Additionally, a comparison with well known correlations was inserted, concluding that no theory can estimate the ionic liquids nanocolloids thermal conductivity. Concluding, the thermal properties of [C4mim][BF4] ionic liquid and its nanocolloids with Al 2 O 3 , ZnO and MWCNT shows that these nanocolloids uncover great potential for heat transfer applications. • 1-Butyl-3-methylimidazolium tetrafluoroborate thermal conductivity is experimental determined. • The thermal conductivity of nanocolloids is debated in terms of nanoparticle mass fraction and temperature. • Thermal conductivity correlations are anticipated for [C4mim][BF4] and its nanocolloids. • The thermal diffusivity and Pr number of nanocolloids based on [C4mim][BF4] follow an in depth discussion. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
23. Analysis of flow characteristics and heat transfer regulations for gas turbine blade middle double swirl cooling under different nozzle numbers.
- Author
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Li, Hongwei, Gao, Yuanxi, Li, Chao, Du, Changhe, and Hong, Wenpeng
- Subjects
- *
SWIRLING flow , *GAS turbine blades , *HEAT transfer , *NOZZLES , *NUSSELT number , *REYNOLDS number - Abstract
In this paper, the gas turbine blades middle double swirl cooling structure under diverse number of nozzles N are constructed to explore the heat transfer and flow behavior. The k-ω turbulence model are applied and the inlet coolant Reynolds number is 12500. The N vary by 4 to 11 and two cases are investigated. For case 1, the cross-sectional area of each nozzle is 6 mm2 for all structures. For case 2, the cross-sectional area of total nozzles stays the constant at 42mm2 when the N is varied. Results show that, in case 1, when the N increases, the area of the high heat exchange zone decreases but the distribution is more uniform. Moreover, the thermal performance factor ξ gets larger, but the average Nusselt number Nu a decreases significantly. In case 2, when the N increases, the ratio of inclination to nozzle length increases for the jet near the outlet, Nu a is almost constant but the heat transfer uniformity is improved. The best ξ is obtained when the N is 8. For case 1, as the N is increased, the Nu a decreases significantly. Therefore, heat transfer and ξ should be considered by case 2 to select the optimum N. • Middle double swirl cooling models with different nozzle numbers are established. • Effects of nozzle number on flow and heat transfer characteristics are explored by two cases. • When the nozzle number is changed, the cross-sectional area of total nozzles in case 1 is changed, but it unchanged in case 2. • The results show that case 2 is more appropriate and the optimum nozzle numbers should be selected by the way of case 2. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
24. Investigation on the thermophysical properties and transient heat transfer characteristics of composite phase change materials.
- Author
-
Chiu, Yu-Jen, Yan, Wei-Mon, Chiu, Han-Chieh, Jang, Jer-Huan, and Ling, Guang-Ya
- Subjects
- *
THERMOPHYSICAL properties , *HEAT transfer , *PHASE change materials , *MICROENCAPSULATION , *GRAPHITE - Abstract
Abstract In this paper, the thermophysical properties and transient heat transfer characteristics of composite phase change materials (CPCMs) were investigated numerically and experimentally in details. Two kinds of microencapsulated phase change materials (MEPCMs) paraffin with melting temperatures of 28 and 37 °C, respectively, were employed in this paper. The CPCMs were fabricated by intercalating expanded graphite (EG) with average diameter of 45 m into MEPCMs. The addition amount of EG were 10%, 30%, and 50% in weight. The thermophysical properties, including density, thermal conductivity and specific heat, of the CPCMs were measured and the latent heat and specific heat were calculated from data with differential scanning calorimetry (DSC). In the experiment, the square enclosure has a cross-section dimension of 100 by 100 mm and it was 15 mm in thickness. The top side wall of the enclosure was heated with isothermal cooling on the bottom side wall while the remaining side walls were thermally insulated. The numerical model which is designed to meet the conditions of the experimental parameters was employed to examine the transient heat transfer characteristics for the CPCMs in the enclosure. Results show that MEPCMs with increasing EG would increase the thermal conductivity and the heat transfer rate. However, the specific heat of CPCMs would decrease. The numerical predictions agree well with the experimental data. In addition, the results disclose that the CPCMs could enhance the rate of heat transfer and energy storage, but minor loss in total energy storage. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
25. A scientometric study of heat transfer journal literature from 1900 to 2017.
- Author
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Tsay, Ming-yueh and Lai, Chien-hui
- Subjects
- *
HEAT transfer , *MASS transfer , *PUBLISHED articles , *PERIODICAL publishing , *SCIENTOMETRICS - Abstract
Abstract The present study conducts a scientometric study of the journal literature of heat transfer from 1900 to 2017 based on the database of Web of Science, 2018. A total of 120,628 items resulted from topic search using "heat transfer" as the search term. The results of this work reveal that the literature on heat transfer grows exponentially with an annual growth rate of about 9.71% for the last century the first two decades of this century through the emergence of new subjects, identified through word cloud of authors' keywords. The document types, countries and languages, journal distribution, number of authors, institution productivity and paper citations are analyzed. Highly productive journals and authors and highly cited papers are identified. The results reveal that USA and China are the two most productive countries contributing 17.4% and 14.3%, respectively. About 90% of papers are published with co-authors and 73% of the paper was published with two to four authors. The author distribution follows the trend of Lotka's law, with 61.3% of the authors published only one paper, and 15.9% of the authors published two papers. International Journal of Heat and Mass Transfer is the most productive journal contributing 9.4% of the publications. Most highly cited papers are identified and found to be consist with the emergence of new subjects in heat transfer. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
26. Study on heat transfer model of solid rocket motor combustor under high-temperature two-phase flow scour state.
- Author
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Yang, Liu, Zhichao, Dong, Haifeng, Wang, Yuxuan, Zou, Yonggang, Gao, and Zilong, Wang
- Subjects
- *
HEAT transfer , *ROCKET engines , *MULTIPHASE flow , *MATHEMATICAL forms , *TWO-phase flow - Abstract
To address the issues with the multi-phase flow and heat transfer characteristics of the gas inside solid rocket motor combustor, this paper first establishes a mathematical model form that can express the heat transfer characteristics between gas and wall, and obtains the mathematical model of heat transfer by means of experiment and numerical simulation. The results show that heat transfer in the wall surface has obvious hysteresis during the actual working process of solid rocket motor, and that temperature in the wall surface will gradually reach the peak value after the motor works. The heat transfer trend between the numerical simulation results and the experimental data is relatively consistent, and the errors of heat transfer calculation in the stable working section of the motor can be controlled by 15%. It shows that the calculation model with the Sommerfeld number as the criterion selected in this paper can better reflect the heat transfer characteristics between the alumina droplet and the wall in combustor. The maximum error between the fitted value and calculated value is 9.43%, which indicates that the numerical model of heat transfer established under the state of two-phase gas and wall scouring has certain reliability. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
27. Recent advances of selected passive heat transfer intensification methods for phase change material-based latent heat energy storage units: A review.
- Author
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Rogowski, M. and Andrzejczyk, R.
- Subjects
- *
HEAT storage , *HEAT transfer , *ENERGY storage , *LATENT heat , *PHASE change materials , *MELTING points , *EVIDENCE gaps - Abstract
The following article overviews recent studies regarding heat transfer enhancement methods, explicitly focusing on fins and coils utilization, in phase change material-based latent heat thermal energy storage systems. It discusses the influence of various geometrical and material parameters on the melting and solidification processes, as well as the orientation of the heat transfer surface within the storage tank. Additionally, the article examines the use of a range of phase change materials regarding their melting temperature. Results show that there are research gaps regarding a few ranges of phase change materials of certain previously studied melting points. This paper's main goal was to detect possible research gaps within the phase change studies field. It should be highlighted that a vast amount of numerical studies of both finned and coiled geometries is in need of experimental verification. More than 62% of analyzed studies were performed numerically, while only 37% were performed experimentally. What is more, there were only a few studies concerning experimental investigations for melting temperatures higher than 60 °C. Furthermore, the majority of experimental as well as numerical studies were concerned only with melting phenomena. This paper also advocates for more standardized studies regarding coil geometries using non-dimensional parameters. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
28. Experimental and numerical investigation on the mechanisms of novel heat transfer deterioration of supercritical CO2 in vertical tubes.
- Author
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Yang, Zenan, Wang, Hao, Guan, Ben, Yang, Haiwei, Li, Zehuan, and Wang, Ge
- Subjects
- *
HEAT transfer , *SUPERCRITICAL carbon dioxide , *HEAT flux , *KELVIN-Helmholtz instability , *BRAYTON cycle , *CARBON dioxide - Abstract
Understanding the mechanisms of supercritical CO 2 heat transfer deterioration (HTD) has significant importance for ensuring the safety and reliability of supercritical Brayton cycles. Therefore, the effects of mass flux, wall heat flux, and tube diameters on the heat transfer characteristics of supercritical CO 2 inside vertical tubes are studied using experimental and numerical methods. Results indicate that the heat transfer performance is positively influenced by an increase in mass flux and heat flux, as well as a decrease in tube diameter. When HTD occurs, the overall heat transfer performance is indeed significantly compromised. When the bulk fluid temperature exceeds T pc , the thermal acceleration effect amplifies the mainstream velocity, stabilizing the Kelvin-Helmholtz instability between the pseudo-two-phases, thereby causing a new type of HTD that is named Type II HTD in this paper. The so-called post-dryout HTD occurs when the bulk temperature surpasses T +, causing a complete transition from pseudo-liquid to pseudo-gas state and resulting in a pseudo-single-phase flow. The heat transfer capability of the low-density and low-thermal-conductivity pseudo-gas diminishes as the temperature rises, leading to post-dryout HTD. The present work explains the mechanisms of two types of HTD and highlights the similarities between subcritical boiling and supercritical pseudo-boiling flow structures. This study also establishes a theoretical foundation for understanding pseudo-two-phase flow patterns during pseudo-boiling. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
29. Enhancement and optimization of cryogenic metal tube chilldown heat transfer using thin-film coating, I. Effects of flow mass flux and coating layer thickness.
- Author
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Wang, Hao, Huang, Bohan, Dong, Jun, Chung, J.N., and Hartwig, J.W.
- Subjects
- *
FLUX flow , *HEAT transfer , *LIQUID nitrogen , *SURFACE coatings , *THERMAL conductivity , *REYNOLDS number , *TUBES - Abstract
This paper is the first of a two-part series that presents experimental data and analysis on the liquid nitrogen quenching heat transfer process of a stainless-steel tube with an inner surface low-thermal conductivity thin-film coating. The experimental data covers a wide range of flow mass fluxes (43 to 1077 kg/m2s). The experiments were conducted using test tubes with four different coating thicknesses to investigate the effects of various Teflon coating thicknesses. An analysis of the chilldown time and LN 2 mass consumption data are presented to evaluate the effects of the flow mass flux, axial distance from the tube inlet, and coating layer thickness. The chilldown time decreases with increasing flow Re. However, the chilldown mass consumption increases with increasing flow Re. In general, the larger the flow Reynolds number, the lower the percentage reduction in chilldown time is observed. For the percentage reduction in the chilldown time by the coating, the minimum is 27.8% for the tube with 7-layer coating at flow of Re = 100,000 and the maximum is 61.3% for the tube with 14-layer coating at flow of Re = 10,000. The percentage reduction in mass consumption due to coating falls in the range between 35.3% and 54.1%. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
30. Study on heat transfer enhancement performance of cooling channel with elliptical dimples in a proton exchange membrane fuel cell.
- Author
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Zhang, Xiang, Huang, Ying, Ma, Zongpeng, and Gao, Tong
- Subjects
- *
PROTON exchange membrane fuel cells , *HEAT transfer , *NANOFLUIDS - Abstract
Cooling channel (CC) design is an effective measure to improve the internal thermal management of proton exchange membrane fuel cells (PEMFC). In this paper, a new elliptical dimple (EDC) cooling channel structure is proposed. The heat transfer and flow characteristics of EDC, circular dimpled cooling channel (CDC), and smooth cooling channel (SC) are compared by numerical simulation method, and the influence of elliptical dimple structural parameters on their performance is discussed. The serpentine CC with elliptical dimples is further compared with the traditional serpentine CC. The results indicate that the EDC is more effective than the other two types due to the narrow surface of the elliptical dimple, which enhances fluid flow and creates a region at the trailing edge of the vortex that promotes heat exchange. It is worth noting that lengthening the elliptical dimple leads to reduced performance, while elongating it initially improves but eventually decreases performance. This study found that the EDC with an elliptical dimple of 0.1 mm depth and 0.6 mm length outperformed the SC, resulting in a 10.6% improvement. Furthermore, the elliptical dimple serpentine cooling channel was found to enhance heat transfer and reduce pressure loss. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
31. An improved numerical model based on the equivalent thermal conductivity method for downhole thermal management systems.
- Author
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Peng, Jiale, Lan, Wei, Deng, Chao, Wei, Fulong, Ding, Siqi, Hu, Run, Shang, Bofeng, and Luo, Xiaobing
- Subjects
- *
THERMAL conductivity , *HEAT radiation & absorption , *HEAT convection , *HEAT transfer , *THERMAL properties - Abstract
The electronics in logging tools are susceptible to thermal failure due to the extreme thermal environment. Passive thermal management system (PTMS) has been proven to protect the electronics for several hours. In this paper, a numerical model based on the equivalent thermal conductivity method was developed to determine the transient temperature of downhole electronics. Compared with the traditional analytical model or numerical model considering only one single heat transfer process, the complex heat transfer in the logging tool were comprehensively considered through the proposed model. Briefly, the heat transfer processes in the vacuum bottle were theoretically calculated rather than empirically acquired, and the convective and radiative heat transfer inside the vacuum bottle was equated to the temperature-dependent thermal conductivity of air. In addition, the proposed numerical model was compared with experiments and previous numerical models to verify the accuracy of the model, and the temperature deviation of the electronics was within 5 °C. Moreover, the computational time was greatly reduced compared with the traditional three-dimensional numerical simulation process while ensuring the accuracy of calculation. Therefore, the proposed numerical model achieved both computational accuracy and efficiency, which was expected to be widely used in the development of PTMS for logging tools. • A numerical model based on equivalent thermal conductivity method was proposed. • The complex heat transfer processes in PTMS were comprehensively considered. • The proposed model possessed high computational accuracy and efficiency. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
32. Thermal performance maximisation in a complex heat exchanger with solid and hollow cylindrical fins.
- Author
-
Godi, Nahum Y.
- Subjects
- *
HEAT exchangers , *HEAT sinks , *FINS (Engineering) , *REYNOLDS number , *HEAT flux , *VORTEX generators - Abstract
This paper explores the impact of hybridisation and geometric variations in micro heat exchangers featuring cylindrical fins. The primary aim of the study is to maximise the thermal conductance. Solid, half-hollow and hollow circular fins are modeled and mounted on a heat sink with a rectangular flow channel. A high-density heat flux of magnitude 500 W / cm 2 is dissipated on the bottom surface by a microelectronic device. Single-phase water of Reynolds number range of between 400 and 500 is supplied through the inlet of the heat sink to remove the heat at the bottom and in the inner walls of the hollows, while cool air stream of Reynolds number range 10 ≤ Re a ≤ 14 is allowed to convectively flow over the vertical micro cylindrical fins to take away extra heat deposited on the fins. The computation domain is descretised and computational fluid dynamic code applied to solve mathematical equations. The numerical results show that the thermal conductance in the half-hollow fins is 16.4% greater than in the solid fins, and 0.14% higher than the hollow fins in parallel flow, while in counter flow the half-hollow fins increase above the solid fins by 5% and by 0.5% higher than hollow fins. The integrated micro heat sink with half-hollow is superior in both parallel and counter flow. Experimental data is used to validate the numerical prediction. [Display omitted] • A groundbreaking method for cooling micro heat exchangers. • Dual cooling technique in integrated heat sink. • The application of cylindrical fins in an integrated heat sink. • A novel approach to enhance heat transfer efficiency in heat sinks. • A cutting-edge innovation in heat sinks with a hybrid configuration. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
33. Enhancement on heat transfer and reliability of low melting temperature alloy based thermal interface materials.
- Author
-
Liu, Zhao, Wang, Chi-Chuan, Wang, Qiuwang, and Chu, Wenxiao
- Subjects
- *
THERMAL interface materials , *THERMAL resistance , *HEAT transfer , *LOW temperatures , *COPPER foil , *COPPER - Abstract
In this paper, the thermal contact resistance (TCR) of different kinds of thermal interface materials (TIMs) is experimentally investigated. The effect of contact pressure on the thermal resistance of low melting temperature alloy (LMTA) TIMS on different metal substrates has been analyzed in detail. The TCR of all TIMs decreases with the rise of contact pressures. At higher contact pressures, however, the decreasing trend of TCR becomes less pronounced. The adsorption of LMTA by perforated copper foil substrate (PCFS) and copper mesh substrate (CMS) at very high contact pressures removes the leakage phenomenon. However, its thermal resistance is higher than that of samples with a single layer of copper foil substrate (CFS). The PCFS was then parametrically analyzed to obtain the PCF porous ration and LMTA brush weight with the lowest thermal resistance. The results revealed that the TIM samples with a single copper foil substrate exhibited the lowest TCR, but at high pressures, the LMTA is flooded and pumped out. Three different PCFSs were made with 1 mm diameter surface holes and 1.5 mm, 2 mm and 2.5 mm center distances between adjacent holes. All three PCFSs yield the lower thermal resistance than samples with a single layer of CFS at the optimum brush applied LMTA weight. The lowest thermal resistance was achieved by brushing 1.018 g weight of LMTA on a PCF with 19.63% porous ration. The thermal resistance of this sample is only 0.12736 cm2·K·W−1 at 24 MPa. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
34. An overview of passive techniques for heat transfer augmentation in microchannel heat sink.
- Author
-
Sidik, Nor Azwadi Che, Muhamad, Muhammad Noor Afiq Witri, Japar, Wan Mohd Arif Aziz, and Rasid, Zainudin A.
- Subjects
- *
HEAT transfer , *HEAT sinks (Electronics) , *MICROCHANNEL flow , *REYNOLDS number , *AERODYNAMICS - Abstract
Active and passive cooling are the two possible methods for removing heat. An active cooling system is the one that involves the use of energy as opposed to passive cooling that uses no energy. Passive cooling methods are cost effective and more reliable than active cooling due to the absence of moving parts. Microchannel heat sink is one of high-tech devices that have widely considered passive cooling methods especially for electronics cooling. In this paper, the use of passive cooling methods in microchannel heat sink is comprehensively discussed. This paper also present the effects of some important parameters such as the type of channel types, surface roughness, fluid additives, and Reynolds number on the rate of heat transfer in microchannel heat sink. Finally, the conclusions and important summaries were presented according to the data collected. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
35. Experimental investigations on shell and helical coil solution heat exchanger in NH3-H2O vapour absorption refrigeration system (VAR).
- Author
-
Ramesh, R., Murugesan, S.N., Narendran, C., and Saravanan, R.
- Subjects
- *
HEAT exchangers -- Design & construction , *HEAT transfer , *SURFACE area measurement , *NUSSELT number , *REYNOLDS number - Abstract
This paper presents the performance investigation of a shell and helical coil type of Solution Heat Exchanger (SHX) in an ammonia–water vapour absorption system. In an absorption system, SHX is one of the major heat recovery components. The main objective of any heat exchanger design is to achieve minimum heat transfer area required for a given heat duty, as it governs the overall fixed cost content of such a system. The required surface area is decided by the overall heat transfer coefficient. Hence, the heat transfer coefficient (HTC) correlation plays a major role in optimizing the heat exchanger. In this paper, shell and helical coil type of SHX is investigated with more emphasis on the dimensionless correlation of shell side co-efficient, which decides the overall HTC and the size of heat exchanger. From the experimental study, shell side heat transfer coefficient of 510–650 W/m 2 K is obtained with the heat exchanger effectiveness of 0.84–0.9 for the tested conditions. A proposed Nusselt number correlation is compared with the experimental results. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
36. Transport of ice slurry in the pipelines of central air conditioning systems in mining plants.
- Author
-
Niezgoda-Żelasko, Beata
- Subjects
- *
AIR conditioning , *CHILLED water systems , *ICE , *SLURRY , *HYDROSTATIC pressure , *WATER pipelines , *HEAT transfer , *WATER temperature - Abstract
The paper presents the phenomena accompanying the processes of non-adiabatic transport of ice slurry with ice mass fraction values below 20% in the transport sections of the system, assuming the conditions of significant changes in hydrostatic pressure. The subject of the analysis presented herein was to indicate the influence of hydrostatic pressure values on melting and secondary recrystallisation phenomena in the case of medium expansion in a vertical shaft pipeline and a three-chamber PES distributor. The paper proposes a computational model to determine the mass fraction of ice in the downstream section of the supply system: upstream and downstream of the PES distributor. The presented calculation results indicate that a reduction in the mass fraction of ice in the range of 0.004% per 1 m of the pipeline could be observed in vertical shaft pipelines. Maximising the enthalpy flux of the slurry at the inlet to the secondary circuit and minimising the temperature of the return water to the chiller favours mixing rates in the PES three-chamber distributor below 7%, which increase as the mass fraction of ice decreases. • Ice slurry applications in central air-conditioning systems of mining plants. • Ice slurry flow and heat transfer in shaft pipelines and PES distributors. • Ice slurry melting and recrystallisation in primary and secondary circuits. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
37. Numerical investigation on thermal performance of thermoelectric-cooler integrated cold plate of thermal control liquid loop in spacecraft.
- Author
-
Gao, Li-Jun, Xu, Hui-Juan, Zhang, Xin, Wang, Ji-Xiang, and Wang, Ao-Bing
- Subjects
- *
TEMPERATURE control , *SPACE stations , *HEAT transfer , *MASS transfer , *LIQUIDS - Abstract
The traditional single-phase fluid loop (SFL) and traditioanl thermal control algorithm can barely control the temperature rapidly. Thermoelectric cooler (TEC) has been proved to be a good thermal controller because of its high reliability, liquid-free characteristics, and fast response. This paper proposes a TEC-based precooling module that resides in front of the cold plate (CP), and consists of a TEC-CP system, manifesting a high compatibility between the novel precooling module and traditional SFL. The TEC-CP system was designed, and a mathematical model of heat and mass transfer was developed to numerically investigate the effects of the geometric parameters, TEC operating conditions, and liquid cooling states of the precooling module upon payload thermal performance. Through analysis, an optimal TEC-based precooling module with optimal geometric dimensions was attained, where the coolant temperature was decreased by 13.04 K, resulting in a 28.98% reduction compared to that without the precooling module. Transient results also demonstrate that the temperature response time can be within 3 min, indicating a fast response system for temperature control. Results outlined in this paper provide structural and data references for future designs of scientific rack-level thermal control loops in space stations. • A novel thermoelectric-cooler (TEC)-based precooling module is proposed. • It provides local rapid cooling capacity for traditional space thermal management. • The precooling module is optimized in terms of thermal performance and COP. • The COP of TEC is needed to be sacrificed to obtain the optimal cooling capacity. • Compared with the traditional one, the focused temperature can be decreased by 28.98%. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
38. Forming experiment of extruded tube with crossed ellipsoidal dimples and numerical investigation on heat transfer enhancement and flow characteristics.
- Author
-
Zheng, Jiyu, Liang, Zheng, Zhang, Liang, Zhou, Jiawei, and Yan, Zhongchao
- Subjects
- *
HEAT transfer , *THERMAL hydraulics , *TUBES , *BOUNDARY layer (Aerodynamics) , *DIMENSIONLESS numbers , *MECHANICAL models - Abstract
In this paper, an extruded tube with crossed ellipsoidal dimples was proposed to achieve heat transfer enhancement. This extruded tube was produced by mechanical extrusion, and an experiment was carried out to confirm the validity and rationality of the manufacture. The experimental results revealed that the error between geometric models built by mechanical simulation and actual manufacture was less than 15%. On this basis, the thermo-hydraulic characteristics were analyzed by numerical simulations. The CFD analysis indicated that the extruded tube improves thermo-hydraulic performance because the structure of dimples promotes mixing degree and boundary layer destruction. In addition, the dimensionless number Nu / Nu 0 , f / f 0 and PEC were presented to illustrate the effects of geometry, such as dimple depth, pitch, the semi-major axis of rigid ellipsoidal blocks and dimple configuration. It was found that the maximum PEC = 2.4 was observed when D = 3 mm, P = 25 mm, a = 10 mm and the dimples configuration is cross. The range of Nu / Nu 0 , f / f 0 and PEC for ETCED is 2.1–4.2, 1.75–7.24 and 1.7–2.4. Finally, the overall performance was compared among different enhanced tubes. The results showed that the extruded tube provided better overall performance than other enhanced tubes. The achievement of this paper can be extended to engineering applications in heat transfer enhancement. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
39. Fluid flow and heat transfer of liquid-liquid two phase flow in microchannels: A review.
- Author
-
Abdollahi, Ayoub, Sharma, Rajnish N., and Vatani, Ashkan
- Subjects
- *
FLUID flow , *HEAT transfer , *LIQUID-liquid interfaces , *TWO-phase flow , *MICROCHANNEL flow - Abstract
The fluid flow and heat transfer behavior of liquid–liquid two phase flows have led to significantly improve the heat transfer rates in microchannels. Both numerical and experimental studies are reviewed in this paper to gain useful insights into the effect of a number of parameters such as film thickness, Peclet number, working fluid and flow geometry on hydrodynamic and thermal behavior of microchannels using liquid-liquid two phase flow. In addition, the paper summarises information about common correlations proposed to predict the pressure drop and heat transfer coefficient in the form of Nusselt number (Nu). The present study shows that there is little agreement across the literature between measured pressure drop and Nusselt number and predictions based on these correlations. Finally, the conclusions and important summaries, and some possible future development of this field are presented. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
40. Three-dimensional simulation of conjugate heat transfer using the hybrid lattice Boltzmann-finite difference method.
- Author
-
Benhamou, Jaouad, Lahmer, El Bachir, and Jami, Mohammed
- Subjects
- *
THERMAL conductivity , *HEAT transfer , *RAYLEIGH number , *NATURAL heat convection , *HEAT flux , *LIQUID-liquid interfaces , *VORTEX generators - Abstract
This paper presents a three-dimensional numerical study of natural convection and conduction thermal phenomena using MRT-lattice Boltzmann and finite difference approaches. Conduction is examined using a simple conjugate heat transfer technique, which is predicated on the assumption of continuity of heat flux and temperature at the solid/fluid interfaces, instead of utilizing the conventional method based on the solution of the conduction equation. Several parameters such as Rayleigh number and thermal conductivity related to common construction materials are also investigated to explore their effects on the evolution of heat transfer. The obtained results show that augmentation of the Rayleigh number increases the quality of heat transfer by around 35–293% for various values of thermal conductivity ratio (solid/fluid). While the increase in thermal conductivity ratio enhances the heat transfer rate by about 212–685%, where the maximum rate of heat exchange is still the same for the thermal conductivity ratio ≥1000. Entropy generation is also examined in this paper to evaluate the efficiency of our studied system. The performed investigations indicate that the rate of entropy generation due to heat transfer, friction, and total entropy generation varies significantly with increasing Rayleigh number and thermal conductivity of the solid. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
41. Thermal effects of water immersion on spray cooling in non-boiling zone.
- Author
-
Li, Jun, Song, Shibo, Shi, Hong, Xu, Yizhe, Meng, Erlin, and Zhou, Bo
- Subjects
- *
WATER immersion , *SPRAY cooling , *GEOTHERMAL resources , *HEAT flux , *HEAT transfer - Abstract
Spray cooling shows significant advantages in thermal control of high heat flux components. However, rapid drainage problem with the spray chamber can affect the reliability and stability of the cooling system. It can be solved by means of immersion. The focus of this paper is to conduct a comparative study of the heat transfer performance between spray cooling (SC) and immersed spray cooling (ISC). It is proved that with reasonable control of immersion state and spray pressure, the immersion does not worsen the heat transfer, but even helps to enhance it with a maximum enhancement ratio of 12.2%. The immersion water temperature and spray pressure play a vital role in the ISC. Wide-angle nozzles are not suitable for ISC applications. The immersion deteriorates the spray cooling by up to 50.1% when the spray angle is 83°. This paper can be a guide to the structural design of the spray chamber. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
42. Automatic selection of regularization parameter in inverse heat conduction problems.
- Author
-
Pacheco, C.C., Lacerda, C.R., and Colaço, M.J.
- Subjects
- *
REGULARIZATION parameter , *HEAT conduction , *TIKHONOV regularization , *NONLINEAR equations , *LEAST squares - Abstract
This paper presents a fast, robust and automatic approach for selecting the regularization parameter in Tikhonov regularization. The methodology is based on the Generalized Cross-Validation (GCV) method, where the minimum of the GCV curve is sought via a numerical optimization algorithm. Typical convergence issues near the global minimum are addressed by changing the variables in the optimization problem in an appropriate fashion. Evidences for the effectiveness of the proposed approach are presented by performing three numerical experiments, consisting of linear and nonlinear inverse heat conduction problems. The obtained estimates are in good agreement with the reference values, showing that the obtained solutions in both problems were appropriately regularized. In this methodology, inverse problem needs not be solved with multiple regularization parameter candidates. Instead, the inverse problem is solved only once, using the optimal parameter. This feature is even more pressing in nonlinear problems, for the optimal regularization parameter may change during the iterative solution of the least squares problem, thus being adjusted at each iteration. Therefore, manual selection of the regularization parameter is not necessary, thus yielding an automatic selection methodology. Finally, as for the "robust" statement, it was made based on the numerical experiments shown on the paper, where the optimal regularization parameters for each problem vary in orders of magnitude. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
43. Study on flow and heat transfer characteristics of phase change synergistic combination finned liquid cooling plate.
- Author
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Zhang, Furen, Liang, Beibei, He, Yanxiao, Gou, Huan, Zhu, Yilin, Lu, Fu, and Xiao, Kang
- Subjects
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PHASE change materials , *HEAT transfer fluids , *HEAT transfer , *BATTERY management systems , *NUSSELT number , *COOLING of water , *REYNOLDS number , *FREE convection - Abstract
In order to enhance the heat transfer performance of the battery thermal management system, to obtain a more uniform temperature distribution and to achieve the lightweight design requirements, a new liquid cooling plate design approach with primary and secondary combined fins synergistic phase change materials and nanofluid is proposed in this paper. Based on the traditional square fins, 10 new improved fin design options are proposed in this paper. Firstly, the thermal and flow characteristics of the 10 new improved fins are compared and analyzed, and the optimization is carried out. Next, the optimal model is obtained by considering the primary fin size and introducing the secondary fins of the partitioned combination for optimization. Compared to the traditional square fins, the average temperature is reduced by 0.288 °C and the pressure drop is reduced by 1.287 Pa (17.42%). Then, based on the optimal model, the thermal performance of the combined filling method and thickness of PCM is discussed and analyzed for different Reynolds number conditions. The results indicated that the smaller the Reynolds number, the more significant the heat dissipation effect of the filled PCM. The optimal model with PCM filling reduces the mass by 41.4 g (68.86%) compared to the model without PCM, with significant lightweighting effect. Finally, to further improve the thermal performance of the system, different types of nanoparticles with different volume fractions are introduced into the system. Compared to pure water liquid cooling, the Nusselt number can be increased by 9% to 78%, and the heat dissipation effect is significantly improved. • Based on the traditional directional fins, 10 new and improved fins are proposed. • Thermal performance of the system was improved after introduction the secondary fins. • A new liquid cooling plate with PCM synergistic combination fins was proposed. • The mass of the optimal model after filling the PCM was reduced by 41.4 g (68.86%). • Nusselt number of system can be improved by 9% to 78% after introduction nanofluid. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
44. Study on heat transfer model of roughness wall in supersonic two-phase flow of solid rocket motor.
- Author
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Yang, Liu, Yonggang, Gao, Pengfei, Zhu, Yuxuan, Zou, and Zhichao, Dong
- Subjects
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HEAT transfer , *SUPERSONIC flow , *ROCKET engines , *NUMERICAL calculations , *SOLIDS - Abstract
In order to establish the heat transfer model of solid rocket motor nozzle expansion section based on roughness wall, an appropriate heat transfer model is proposed, and the heat transfer model is established by the combination of experiment and numerical calculation. Results demonstrate that: 1) with the increase of the depth of temperature measuring points in different sections, the temperature increases and the corresponding time response accelerates. With the increase of the expansion ratio of temperature measuring sections, the temperature decreases. 2) The overall trend between the calculation results and the experimental measurement results is relatively consistent, which indicates that the numerical calculation method established in this paper has certain applicability and can accurately reflect the heat transfer characteristics of solid rocket motor nozzle expansion section based on real roughness wall. 3) The establishment of heat transfer model is completed using the segmented method, and the error between Nu calculated by the proposed heat transfer model and Nu calculated by numerical calculation is controlled within 21% and 13% in the first and second segments respectively. It shows that the heat transfer model established in this paper has certain rationality and reliability. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
45. Thermal performance promotion of a novel double-tube heat exchanger by helical fin with perforations.
- Author
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Song, KeWei, He, YiTan, Zhang, Qiang, Wu, Xiang, He, AiLing, and Hou, QingZhi
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HEAT exchangers , *FINS (Engineering) , *HEAT transfer , *VORTEX generators , *HEAT transfer fluids , *TECHNOLOGY transfer - Abstract
Double-tube heat exchangers are widely used in many fields. A novel double-tube heat exchanger with a perforated helical fin on the annulus side is proposed in this paper for thermal performance promotion. The effect of different perforation diameters ranging from 0 to 12 mm on the fluid flow and heat transfer are numerically studied under a turbulent state with Re ranges between 4000 and 16,000. The results showed that perforation diameter has a significant influence on the thermal performance. There exists an optimum perforation diameter for the best thermal performance. The largest value of Nu in the helical finned annulus increases by 20.2% by perforation, while the corresponding f only increases by 11.0% compared with the normal helical finned configuration without perforation. The thermal performance evaluation factor JF is also improved by up to 16.1% compared with the helical finned configuration without perforation, and is increased by 48.6% compared with the smooth annulus. Correlation formulas of f, Nu, and JF are fitted and the deviations are within ±4%, ±9%, and ± 5% for f , Nu, and JF , respectively. Perforated helical fin is an efficient annular-side heat transfer enhancement technology that can be applied to the optimized design of double-tube heat exchangers. • A novel double-tube heat exchanger with perforated helical fin is studied. • Heat transfer is significantly improved by perforations on the helical fin. • Nu increases by 20.2% with f increases by 11.0% compared with the normal helical fin. • JF increases by 16.1% and 48.6% compared with helical finned and smooth annular tube • Correlations of Nu , f and JF are proposed to facilitate the application of the results. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
46. Lattice Boltzmann method study of pool boiling on an electrowetting substrate.
- Author
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Chen, Yu-Jie, Gong, Jun-Hua, Ding, Jing, Yu, Bo, Chen, Li, Li, Yi-Gang, and Tao, Wen-Quan
- Subjects
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EBULLITION , *LATTICE Boltzmann methods , *HEAT transfer coefficient , *HEAT transfer , *HEAT flux , *NUCLEATE boiling - Abstract
Electrowetting has attracted significant attention in condensation, but its application in enhancing pool boiling heat transfer is very limited. In this paper, the lattice Boltzmann method is adopted to investigate the pool boiling heat transfer on electrowetting surfaces with different electrode configurations. The wettability of the baseline hydrophobic surface above the electrode will change to hydrophilicity once a voltage is applied. The differences in heat transfer and boiling phenomenon between the hydrophilic and hydrophobic surfaces without electrodes are illustrated firstly by the density contours and boiling curves. Then, the possibility of electrowetting in improving the heat transfer coefficient (HTC) and critical heat flux (CHF) is verified by comparing with baseline hydrophobic and patterned-coating surfaces, and different boiling heat transfer regimes are illustrated in detail. Furthermore, based on the heat transfer characteristics of the electrowetting surfaces with different electrode configurations, a surface with temperature-dependent electrodes is obtained to comprehensively enhance heat transfer from the onset of nucleate boiling (ONB) to CHF. • The possibility of electrowetting in enhancing pool boiling heat transfer is verified. • Electrode configurations greatly affect heat transfer characteristics. • Temperature-dependent electrowetting surface enhances pool boiling heat transfer from ONB to CHF. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
47. Heat transfer efficiency enhancement of gyroid heat exchanger based on multidimensional gradient structure design.
- Author
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Chen, Fei, Jiang, Xin, Lu, Chenxi, Wang, Yangwei, Wen, Pin, and Shen, Qiang
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HEAT exchangers , *HEAT transfer , *HEAT transfer coefficient , *HEAT convection , *COMPUTATIONAL fluid dynamics , *VORTEX generators , *CONVECTIVE flow - Abstract
Nowadays, a bio-inspired heat exchanger incorporating a triply periodic minimal surface (TPMS) structure has demonstrated great potential in the fields of new energy research and aerospace, which necessitates achieving a balance between low volume and high heat transfer efficiency while maintaining low pressure drop. In this paper, the adjustable heat efficiency of the heat exchanger with TPMS in gradient thicknesses is specially designed. A steady-state conjugate heat transfer (CHT) model is coupled with computational fluid dynamics (CFD) analysis. In addition, the temperature profile and velocity streamline are also checked to analyze the fluid flow behavior of the radiator. The results show that the convective heat transfer coefficient of the Gyroid with gradient level set values is 26.02–60.10% higher than that of the uniform Gyroid model, and the pressure drop is decreased by 9.66–18.05%. Both high heat transfer efficiency and low pressure drop can be achieved when the thickness is 0.2–0.3 mm and Re is 100–125. The heat exchangers with a TPMS thickness gradient in the ratio of 2:4:6 demonstrate a remarkable enhancement in overall heat transfer efficiency, achieving a 30.22% improvement compared to those with a TPMS thickness gradient in 6:4:2. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
48. Effects of vibration conditions on thermo-hydrodynamic performances of oscillating heat pipes with various diameters.
- Author
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Yao, Feng, Xia, Yujuan, Chen, Xi, Yu, Feng, Zhou, Hua, and Liu, Xiangdong
- Subjects
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FREQUENCIES of oscillating systems , *HEAT transfer , *FLUID flow , *HEAT pipes , *DIAMETER - Abstract
This paper investigates the thermo-hydrodynamic performance of oscillating heat pipes (OHPs) with different inner diameters (1.5 mm ~ 3.0 mm) under vibration conditions. The effects of vibration frequency (25 Hz, 50 Hz, and 100 Hz) and amplitude (0.4 mm, 0.8 mm, and 1.2 mm) on the startup and quasi-steady heat transfer of OHPs were analyzed. Results indicate that increasing vibration frequency promote fluid flow in OHPs, while increasing vibration amplitude has the opposite effect. The impact of vibration frequency and amplitude on hydrodynamic characteristics is more pronounced in OHPs with larger diameters due to additional forces induced by vibrations. The startup performance is firstly weakened and then gradually improved with the increasing vibration frequency, indicating the flow resistance is increased under low-frequency vibration condition. The initial fluid movement in the OHPs starts more easily under low-amplitude vibration condition, and thus the startup performance is optimum when the vibration amplitude is 0.4 mm. In addition, the startup performance of OHP with the inner diameter of 1.5 mm is affected mostly due to the finite fluid volume. The heat transfer performance, for the OHP with 3 mm inner diameter, will not be improved until the vibration frequency is higher than 100 Hz, and it is reduced most under the vibration amplitude of 0.8 mm. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
49. Heat transfer performance investigation of rotating U-channel supercritical pressure hydrocarbon fuel with intermediate connection section.
- Author
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Dong, Mengqiang, Huang, Hongyan, Feng, Yu, and Qin, Jiang
- Subjects
- *
FOSSIL fuels , *HEAT transfer , *FRICTION losses , *TURBINE blades , *HIGH temperatures - Abstract
To meet the challenge of the high temperatures faced by hypersonic vehicle electricity provision turbine blades, the blades are cooled with hydrocarbon fuel. For reducing the friction loss and improving the thermal performance, this paper designs and investigates the fuel flow mechanism and heat transfer law in the rotating channel with and without intermediate connection section. The results show that the channel with intermediate connection sections can reduce the friction coefficient of hydrocarbon fuel under rotating conditions and enhance the thermal performance. The connection section width H = 2D channel exhibits the best thermal performance and the lowest coefficient of friction. Compared to the channel without intermediate connection section, the thermal performance of the channel with connection section width H = 2 D is maximally enhanced by 3.71 times and the friction coefficient is maximally reduced by 98.9%. Compared to stationary, the thermal performance of the channel with a width of connection section H = 2 D is maximally enhanced by 10.78 times in rotating. Connecting sections will gradually replace 180° top turning sections. When the inlet temperature increases, the thermal performance of the channel can be improved by decreasing the width of the intermediate connecting section. • Channel with intermediate connection section reduces friction factor and improves thermal performance. • Channel TP with connection section is increased by a maximum of 3.71 times and f is decreased by a maximum of 98.9%. • Interaction of connection regions with heat transfer levels in other regions is key reason for h variations. • Connection section is gradually becoming main passageway to bridge the 1st and 2nd channels. • As H increases, h will rise then fall then rise and finally will fall. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
50. Experimental study on bubble dynamics and heat transfer of pool boiling at sub-atmospheric pressures.
- Author
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Wang, Xiang, Liang, Kun, Xu, Jing, Wang, Jigang, and Chen, Xinwen
- Subjects
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EBULLITION , *BUBBLE dynamics , *HEAT transfer , *HEAT transfer coefficient , *HEAT flux , *ATMOSPHERIC pressure - Abstract
Pool boiling, as an efficient phase-change heat transfer method, has attracted extensive attention in recent years. However, the bubble dynamics behavior (BDB) and heat transfer characteristics of pool boiling at sub-atmospheric pressure (sub-ATM) are significantly different from those at or above standard atmospheric pressure (std-ATM). This paper presents experimental results of BDB and heat transfer characteristics of pool boiling at sub-ATM in the range of 30–120 kPa. High-speed backlight imaging technique was adopted. The results show that with the decrease of boiling pressure, the diameter and near circularity coefficient of bubble departure increase, and the frequency and aspect ratio decrease. With the decline in pressure, the critical heat flux (CHF) of pool boiling on the surface of the electric heater decreases. Specifically, the CHF at 120 kPa is 23.2% higher than that at 40 kPa. At sub-ATM, the boiling heat transfer coefficient (HTC) grows with the increase of liquid height. However, the HTC hardly changes with liquid height at std-ATM and higher. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
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