首页期刊导航|Applied thermal engineering
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Applied thermal engineering
Elservier Science Ltd.
Applied thermal engineering

Elservier Science Ltd.

1359-4311

Applied thermal engineering/Journal Applied thermal engineeringISTPSCIEI
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    Design and modeling of novel two-phase heat exchangers for a home cooling system with ice energy storage

    Mokarram N.H.Wang H.
    16页
    查看更多>>摘要:In this study, a novel three-fluid micro-channel evaporator is designed and modeled for a home cooling system with ice energy storage. A two-fluid condenser with similar heat duty is also modeled using micro-channels. Thermal resistance network is used to model the overall heat transfer coefficient of the heat exchangers. The heat transfer model considers the non-symmetric nature of the three-fluid micro-channel evaporator and includes detailed two-phase boiling heat transfer analysis. Similar detailed condensation two-phase heat transfer analysis is conducted for the condenser using the Universal Correlation. The study also conducted extensive code validation for the two-phase boiling and condensation heat transfer correlations before using the code for evaporator and condenser design and analysis. The design conditions for the evaporator and condenser including superheat and subcooling are gathered from ASHRAE standards. The models are expected to accurately predict the heat exchanger sizes for a design requirement, and calculates the fluid outlet temperatures and heat duty for a heat transfer analysis. When combining with the system model of the home cooling system, the evaporator and condenser models can more accurately predict the overall system performance under variable operating conditions. The discretization method results a 62.4 cm length evaporator and a 42.4 cm condenser, which are required to run a 17-kW home-cooling system based on the detailed assumptions and two-phase correlations.
      原文链接:
    • NSTL
    • Elsevier

    Optimal thermal management of server cooling system based cooling tower under different ambient temperatures

    He W.Zhang J.Li H.Liu S....
    10页
    查看更多>>摘要:To develop a highly efficient and energy-saving cooling system in a data center, this study investigates the optimal thermal management both on the internal server cooling cycle and external cold source water cycle under different ambient temperatures based on the principle of minimal power consumption. Taking a server cabinet of 4.8 kW as the case, an internal indirect water-cooled heat sink cycle and an external cooling tower cold source cycle are constructed. A hybrid thermal management model combined with a heat dissipation model and a power consumption model was developed with the aid of MATLAB and TRNSYS. Using this model, the relationship between the chip dissipation performance attached to the fin-type heat sink and the energy consumption performance of the cooling system under different water working conditions and ambient temperatures was analyzed. Finally, to achieve minimal system energy consumption, the optimized inlet temperature and water flow rates corresponding to different ambient temperatures were obtained by fitting expressions that can better serve the optimal design of data center cooling systems. Furthermore, when the optimal value was applied using the year-round temperature of Tianjin, China in the case study, a 21.3% reduction in power consumption and a 4.43% decrease in the power usage effectiveness can be achieved compared to the case without optimization. Therefore, significant power can be saved in a data center cooling system through thermal management optimization.
      原文链接:
    • NSTL
    • Elsevier

    Model predictive control of long Transfer-line cooling process based on Back-Propagation neural network

    Chang Z.-Z.Li M.Zhu K.-Y.Sun L.-R....
    12页
    查看更多>>摘要:As the scale of large cryogenic systems continues to expand, the thermal inertia and nonlinear characteristics of the pre-cooling process of long-distance cryogenic transfer-line become obvious, and the traditional control methods are less effective in controlling such nonlinear large hysteresis time-varying systems. To improve the automation of the pre-cooling process, a Model Predictive Control (MPC) method based on Back-Propagation (BP) neural network as a surrogate inversion model was designed and deployed on a large helium cryogenic system of the Platform of Advanced Photon Source (PAPS). Simulation and test results show that the MPC method can be applied to the automatic control of nonlinear large hysteresis dynamical systems; the BP neural network as a surrogate model can invert the one-dimensional flow heat transfer model better. The actual test results on the PAPS cryogenic system show that the method can realize the automatic pre-cooling of long transfer-line, and the overall cooling effect is stable and efficient, with the maximum absolute temperature difference of no more than 3.2 K and the maximum relative temperature difference of no more than 2.1% from the ideal cooling line.
      原文链接:
    • NSTL
    • Elsevier

    CFD-DEM study of a V-shaped Down-tube pyrolysis Reactor: Flow and heat transfer between heat carrier and biomass

    Kong R.Bi D.Yao D.Zhang Y....
    12页
    查看更多>>摘要:The flow and heat transfer characteristics of heat carrier and biomass particles in a V-shaped down-tube reactor were studied using computational fluid dynamics-discrete element method (CFD-DEM) modeling. The effects of different mass ratios of heat carrier to biomass particles and heat carrier diameters on the temperature distribution, heating rate, and residence time of biomass particles in a reactor were compared. The results showed that the temperature in the reactor increased with the increase of the mass ratio. The simulated results showed that the heating rate and final temperature of biomass powder were better at the mass ratio of 20:1 than other mass ratios (10:1, 15:1, 30:1 and 40:1). The residence time distribution of the biomass particles was found to be approximately normal, but increasing the heat carrier diameter had a significant influence on the residence time of the biomass particles.
      原文链接:
    • NSTL
    • Elsevier

    Liquid carbon dioxide drying and subsequent combustion behavior of high-moisture coal at high pressure

    Kim H.Choi J.Lim H.Song J....
    16页
    查看更多>>摘要:In this work, the combustion and radiation characteristics of high-moisture coal treated with liquid carbon dioxide (LCO2) at high pressure were examined. The coal conversion and gas yield were measured to determine the combustion rate constants at four different temperatures. The particle temperature and radiative heat flux emitted from the burning coal bed were measured using a two-color pyrometer and radiometer, respectively. The changes in the moisture content of the coal microstructure after LCO2 treatment were measured using nuclear magnetic resonance (NMR) and thermogravimetric analysis (TGA). The combustion kinetic results showed faster LCO2–coal slurry combustion, which frequently occurred at low temperatures. The particle temperature and radiative heat flux of the LCO2–coal slurry increased faster to higher steady-state values than those of raw coal. The influence of LCO2 on the combustion of high-moisture coal was not observed on graphite devoid of water or volatile content. This indicates an effective exchange between LCO2 and water in coal micropores when coal is exposed to LCO2. In addition to the TGA data, the LCO2 drying mechanism in high-moisture coal was confirmed using NMR relaxation data. The performance of the LCO2 drying process was compared with that of the conventional boiler with oven drying unit in terms of the water removal effect, combustion, and radiation behavior. An energy analysis was undertaken to calculate the amount of total energy produced from three power cycles occurring in a high-pressure boiler, including one combining the LCO2 drying cycle with the steam power cycle.
      原文链接:
    • NSTL
    • Elsevier

    Numerical investigation of design and operating parameter effects on permeability-differentiated alkaline fuel cell with metal foam flow field

    Xi F.Jiao K.Chen W.Cheng C....
    15页
    查看更多>>摘要:Metal foam (MF) material is recognized as an attractive flow field for the alkaline anion exchange membrane fuel cell (AAEMFC). In this paper, the effect of design parameters (MF thickness and permeability) and operating parameters (operating temperature and back pressure) are investigated and optimized through the numerical study. The maximum temperature of the AAEMFC with MF flow field is lower and temperature distribution is more uniform compared to that of AAEMFC with serpentine flow field. In general, the higher operating temperature decreases the cell performance slightly in the low current density region but enhances the cell performance obviously in the medium and high current density regions. The higher back pressure promotes the cell performance in the low current density region but decreases the cell performance in the high current density region. The anode MF thickness has the significant effect on the cell performance, and the thinner anode MF thickness benefits the cell performance. However, the effect of cathode MF thickness is relatively negligible. The lower permeability of the anode MF and higher permeability of cathode MF lead to the better performance. The permeability-differentiated layout of MFs in anode and cathode sides is proposed for the first time, and it is proven to improve the cell performance effectively due to the enhanced hydraulic permeation and membrane hydration. Electrochemical kinetics, thermal and water transport characteristics (including pressure drop, liquid water transport, membrane water distribution and ohmic loss) are analyzed in detail to explain the cell performance improvement.
      原文链接:
    • NSTL
    • Elsevier

    Visualization research on influencing factors of flat heat pipes

    Zhou J.Liu L.Yang X.Zhang Y....
    13页
    查看更多>>摘要:Flat heat pipes can effectively spread a concentrated high power heat source in a small region into a larger heat dissipation area, which is widely used in the thermal management of electronic devices. In this paper, two different sintered copper powder wick structures are designed to study the effect of porous column height on the heat transfer performance. The results show that the best performance is achieved at the 30% filling ratio under the 15 ℃ cooling water with all the porous columns contacting with the condenser. The heat power is 312.7 W and the thermal resistance is 0.192 ℃/W. As the cooling water temperature increases, the evaporation rate increases, resulting in a decrease in the thermal resistance. But the decrease in temperature difference causes the decline in heat dissipation power. Through the visual observation, it is found that the porous column contacting with the condenser can not only play the role of support and liquid reflow pathway, but also serve as an effective evaporation area to improve the heat transfer performance. While the low porous column cannot transport the condensed liquid and is completely immersed by the liquid under the high filling ratio, which is difficult to promote evaporation rate. In order to improve the performance at air cooling situation, an integrated heat pipe combined the flat heat pipe and fin tubes is designed, which can achieve a heat power of 259.8 W and present excellent temperature uniformity. This research provides the guidelines to optimize the heat transfer performance of porous column wick structures.
      原文链接:
    • NSTL
    • Elsevier

    Experimental study of the heat transfer characteristics of single geothermal fracture at different reservoir temperature and in situ stress conditions

    Shu B.Wang Y.Zhu R.Liu L....
    9页
    查看更多>>摘要:Deep geothermal energy in hot dry rock is a type of renewable energy which can serve as base load energy through enhanced geothermal systems. In previous studies, the effect of reservoir temperature and in situ stress on the heat transfer efficiency from rock to water was studied mainly for rock temperatures less than 100 °C. In this study, two experiments were conducted to explore the heat transfer coefficient and heat extraction efficiency of a single rock fracture with temperatures from 100 to 200 °C, and confining stresses from 4 to 20 MPa. A new heat transfer model for the fluid flow in a single fracture was established and heat transfer coefficient was derived. Experimental results shown that it is feasible to simplify the heat transfer coefficient equation by replacing the temperature of fracture surface with the temperature of rock sample because their difference is only 0.027% to 0.074%. The heat transfer coefficient increases by 21%, 48%, 94%, 117%, and 147%, while the energy extraction rate increases by 37%, 82%, 148%, 197%, and 299%, when rock temperature increases from 100 °C to 120 °C, 140 °C, 160 °C, 180 °C, and 200 °C, respectively. On the contrary, the heat transfer coefficient decreased by 16%, 22%, 27%, and 31%, while the energy extraction rate decreases by 19.3%, 29.0%, 35.7% and 40.4%, as confining pressure increases from 4 to 8, 12, 16, and 20 MPa, respectively. We also find that the temperature and confining pressure have less effect on the energy consumption of pump which is used to run the fluid flow in fracture, and the energy extraction rate is two to forty times of the pump energy consumption rate.
      原文链接:
    • NSTL
    • Elsevier

    Comparative investigations on dynamic characteristics of basic ORC and cascaded LTES-ORC under transient heat sources

    Li Z.Yu X.Jiang R.Huang R....
    15页
    查看更多>>摘要:In order to overcome the thermal power fluctuations of transient heat sources and improve the safety performance of organic Rankine cycles (ORC), a novel combined system that latent thermal energy storage (LTES) using phase change material (PCM) is integrated into an ORC is proposed in this study. In the proposed system, LTES and evaporator have a cascaded configuration where the transient heat source first flows through LTES and then flows into the evaporator, with the fluctuating amplitude largely buffered. To validate the superiorities of the proposed cascaded LTES-ORC system, effects of PCM thermophysical properties including thermal conductivity and melting temperature are evaluated on the dynamic performance of LTES-ORC system, and they are comprehensively compared with that of basic ORC system under step-change and cyclic heat sources. Results indicate that proposed LTES-ORC system achieves significantly smaller fluctuating range of evaporating pressure and superheat degree than basic ORC system under both step-change and cyclic heat sources. Especially, LTES-ORC system has a larger maximum allowable fluctuating limitation range of heat sources and improves the safety performance under fluctuating heat source. In detail, under small-period fluctuating heat sources, LTES-ORC system can bear 15%–20% higher fluctuating amplitude ratio than basic ORC system under the same period of heat source. When the period is within the range of 600–3600 s, about 33%–42% higher fluctuating amplitude ratio can be resisted by LTES-ORC system. In addition, a correlation is proposed and validated to fast predict the maximum allowable fluctuation limitation for LTES-ORC system.
      原文链接:
    • NSTL
    • Elsevier

    A novel hybrid battery thermal management system with fins added on and between liquid cooling channels in composite phase change materials

    Zhang F.Zhai L.Zhang L.Yi M....
    18页
    查看更多>>摘要:In order to lighten and simplify the battery pack structure and avoid problems such as poor heat dissipation caused by uneven liquefaction of phase change materials after the introduction of liquid cooling, so as to effectively improve the heat dissipation performance of the battery pack and control its maximum temperature and maximum temperature difference, a new way of adding combined fins on and between cooling channels in phase change materials was proposed in this paper. The reliability of CFD simulation method was proved by the phase change material battery pack experiment. Firstly, the effect of the combination of different phase change materials on the heat dissipation performance of the battery pack was studied. In order to further reduce the temperature of the battery pack, the liquid cooling mode was introduced this paper. Then, designed and discussed the influences of three liquid cooling channel layout modes on the temperature of the battery pack, and optimized the channel number and spacing of the optimal layout mode. The results showed that the introduction of liquid cooling could effectively reduce the maximum temperature of the battery pack, but the maximum temperature difference of the battery pack would increase slightly. In order to enhance the heat dissipation performance of battery pack without energy consumption, a new method of adding fins on liquid cooling channel was proposed. The effects of three fin arrangements on battery pack temperature were designed and analyzed, and the fin height of the optimal arrangement was optimized. It showed that the reasonable arrangement of fins on the liquid cooling channels could reduce the maximum temperature of the battery pack and improve the temperature uniformity of the battery pack. Finally, the influence of coolant flow on battery pack temperature was analyzed. The results demonstrated that with the increase of flow rate, the decreasing trend of the maximum temperature of the battery pack gradually slowed down, while the maximum temperature difference of the battery pack first decreased and then increased. Compared with the Pure paraffin model, when the flow rate was 3.2 g/s, the maximum temperature of the optimal model was reduced by 18.28 °C (27.63%) and the maximum temperature difference was reduced by 0.74 °C (35.58%).
      原文链接:
    • NSTL
    • Elsevier