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1. Improved modeling analysis on heat transfer performance of deep coaxial borehole heat exchanger with different operation modes

Author

Zhenyuan Guo, Yanjun Dai, Jing Zhang, Xiaoli Gui, and Yingqi He

Subjects
Deep coaxial borehole heat exchanger, Simplified model, Heat transfer performance, Operation mode, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The deep coaxial borehole heat exchanger (DCBHE) is a highly promising technology which has garnered significant attention. However, there has been a notable scarcity of studies focusing on the physical and mathematical models essential for accurately describing the heat transfer processes involving the DCBHE, well, and rock. This study addresses this gap by employing an improved numerical heat transfer method through programming to conduct an in-depth analysis of the heat transfer performance. The model is solved using the finite volume method (FVM) and validated using experimental data from an existing literature. The simplified effect of pipes and filling material on the heat transfer performance of the DCBHE are analyzed. Furthermore, the characteristics of outlet temperature, heat extraction power, change rate, reduction degree of DCBHE with different operation modes are also analyzed, considering both the heat extraction of one season and 20 years. The results indicate that the simplification of the outer pipe and filling material as thermal resistances is unreasonable while the simplification of inner pipe is acceptable. The maximum outlet water temperature decreases year by year, as the rock-soil temperature fails to recover to its initial level. The water outlet temperature decreases with the run stop ratio while the heat extraction increases. Moreover, the operation mode of 2:2 is recommended both in one heat extraction season and 20 years operation.

Published
2024
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2. A machine learning assisted prediction of potential biochar and its applications in anaerobic digestion for valuable chemicals and energy recovery from organic waste

Author

Pengshuai Zhang, Tengyu Zhang, Jingxin Zhang, Huaiyou Liu, Cristhian Chicaiza-Ortiz, Jonathan T. E. Lee, Yiliang He, Yanjun Dai, and Yen Wah Tong

Subjects
Anaerobic digestion, Biomass-based biochar, Machine learning, Bioenergy recovery, Energy industries. Energy policy. Fuel trade, HD9502-9502.5, Renewable energy sources, TJ807-830
Abstract

Abstract The utilization of biochar derived from biomass residue to enhance anaerobic digestion (AD) for bioenergy recovery offers a sustainable approach to advance sustainable energy and mitigate climate change. However, conducting comprehensive research on the optimal conditions for AD experiments with biochar addition poses a challenge due to diverse experimental objectives. Machine learning (ML) has demonstrated its effectiveness in addressing this issue. Therefore, it is essential to provide an overview of current ML-optimized energy recovery processes for biochar-enhanced AD in order to facilitate a more systematic utilization of ML tools. This review comprehensively examines the material and energy flow of biochar preparation and its impact on AD is comprehension reviewed to optimize biochar-enhanced bioenergy recovery from a production process perspective. Specifically, it summarizes the application of the ML techniques, based on artificial intelligence, for predicting biochar yield and properties of biomass residues, as well as their utilization in AD. Overall, this review offers a comprehensive analysis to address the current challenges in biochar utilization and sustainable energy recovery. In future research, it is crucial to tackle the challenges that hinder the implementation of biochar in pilot-scale reactors. It is recommended to further investigate the correlation between the physicochemical properties of biochar and the bioenergy recovery process. Additionally, enhancing the role of ML throughout the entire biochar-enhanced bioenergy recovery process holds promise for achieving economically and environmentally optimized bioenergy recovery efficiency. Graphical Abstract

Published
2024
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3. Numerical and experimental investigation of the flow and heat transfer characteristics for cold storage heat exchanger

Author

Zhengkun Jiang, Da Wang, Yanjun Dai, and Shuangxi Xu

Subjects
Freezing, Coolant temperature, Natural convection, Inhomogeneity, Tube diameter, Engineering (General). Civil engineering (General), TA1-2040
Abstract

Decreasing the freezing time of the cold storage heat exchanger was an effective way to reduce the risk of cold chain breakage and the fluctuation of cold chain temperature. A validated unsteady mathematical model of the cold storage heat exchanger was established to analyze the transient evolution of temperature, velocity, ice distribution, and heat transfer coefficient for different diameters of heat transfer tubes and coolant temperatures. The results showed that there were four stages of temperature in the cold storage heat exchanger, namely the primary cooling stage, the freezing stage, the secondary cooling stage, and the constant temperature stage. The ice fraction distribution and the heat transfer coefficient were inextricably linked to the water's natural convection. The average heat transfer coefficient decreased with decreasing coolant temperature and increasing heat transfer tube diameters. The freezing time decreased with the coolant temperature and the diameter of the heat transfer tubes decreasing. The tendency of the inhomogeneity of ice distribution first increased with the ice fraction up to 0.75 and then decreased with the ice fraction over 0.75. The inhomogeneity decreased with the coolant temperature increasing when the diameter of the heat transfer tubes was greater than 2 mm.

Published
2024
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4. Study on the effect of semi-transparency on thermal insulation performance of silica aerogel composites

Author

Yanjun Dai, Yingqi He, Dongdong Yu, Jianbiao Dai, Yungang Wang, and Fan Bai

Subjects
Aerogel composites, Thermal insulation performance, Semitransparency, High temperature, Two-flux approximation model, Engineering (General). Civil engineering (General), TA1-2040
Abstract

This paper centralizes its focus on elucidating the distinctive thermal insulation performance of silica aerogel composites, emphasizing their semitransparent attributes under diverse heating methodologies. Firstly, the theoretical prediction of conductive thermal conductivity is undertaken utilizing the spherical hollow cube model and Davies model. Subsequently, the radiative thermal conductivity is numerically derived employing the two-flux approximation model, integrating experimental measurements of optical radiation characteristic parameters. The prediction results under high-temperature are validated by the measured data via a Hot Disk instrument, utilizing the transient plane source method. Finally, the influence of semitransparent properties of the aerogel composites on thermal insulation performance is exhaustively investigated. This is conducted through a meticulous examination of temperature responses resulting from distinct heating modalities, namely contact heating, quartz lamp heating, and arc heated wind tunnel heating. The findings discernibly illustrate that these diverse heating mechanisms significantly impact the thermal insulation performance of aerogel composites endowed with semitransparent characteristics.

Published
2024
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5. Mesoporous Silica‐Guided Synthesis of Metal–Organic Framework with Enhanced Water Adsorption Capacity for Smart Indoor Humidity Regulation

Author

Lurong Ge, Yaohui Feng, Yanan Xue, Yanjun Dai, Ruzhu Wang, and Tianshu Ge

Subjects
indoor humidity regulation, mesoporous silica, metal–organic frameworks, solar energy, water adsorption, Physics, QC1-999, Chemistry, QD1-999
Abstract

Metal–organic frameworks (MOFs) are promising for indoor humidity regulation due to steep stepwise water uptake and moderate regeneration temperature. Current approaches for performance improvement of MOFs such as impregnating hygroscopic salts and grafting functional groups face the challenge of corrosion and instability. Herein, a template‐guided tuning strategy is proposed to synthesize binary nanocomposite. Highly ordered mesoporous channels of MCM‐41 provide uniform nucleation sites for MOF growth, enabling a 21.5% promotion of specific surface area (3188.14 m2 g−1) and 23.4% improvement of water uptake (1.53 g g−1 at 20°C/90% relative humidity) for the nanocomposite compared with parent MIL‐101(Cr). The fast kinetics and superior stability together guarantee its practical application. Further, a paradigm of continuous indoor humidity regulation driven by sunlight is demonstrated, which realizes smart regulation of the indoor humidity to the human comfort zone (40–60%) with near‐zero energy input.

Published
2023
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6. Concentrating solar assisted biomass-to-fuel conversion through gasification: A review

Author

Dequan Xu, Xinzhuang Gu, and Yanjun Dai

Subjects
concentrated solar, biomass gasification, solar fuel, syngas, intermittence management, General Works
Abstract

Solar energy, the most abundant and exploitable renewable energy resource, is regarded as a major energy source for the future. Nevertheless, solar irradiation is characterized by relatively low energy density, intermittency and uneven distribution. Storage of solar energy for usage during non-solar times is required to match supply and demand rates in today’s society. In this context, the application of solar energy for converting into storable, transportable, and energy-dense fuels (i.e., solar fuels) is an attractive option, with the advantage of contributing to promoting the commercialization of solar power technologies. Solar assisted biomass gasification is a promising pathway to produce solar fuels. With concentrated solar energy providing reaction heat, carbonaceous materials can be converted to high grade syngas, which could be further synthesized into useful hydrocarbon fuels. In such process, solar energy is stored in a chemical form, with solar spectrum fully utilized. Compared with autothermal biomass gasification, the usage of high-flux concentrated solar radiation to drive endothermic gasification reactions improves energy efficiencies, saves biomass feedstocks, and is relatively free of combustion by-products. This review presents a comprehensive summary of solar assisted biomass gasification, including concentrating solar technology, fundamentals of solar biomass gasification, state-of-the-art solar gasifier designs, strategies for solar intermittence management, and downstream applications.

Published
2023
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8. A Review on Enhancing Cupriavidus necator Fermentation for Poly(3-hydroxybutyrate) (PHB) Production From Low-Cost Carbon Sources

Author

Le Zhang, Zicheng Jiang, To-Hung Tsui, Kai-Chee Loh, Yanjun Dai, and Yen Wah Tong

Subjects
polyhydroxyalkanoates, biodegradable plastic, microbial fermentation, waste management, resource recovery, process engineering, Biotechnology, TP248.13-248.65
Abstract

In the context of a circular economy, bioplastic production using biodegradable materials such as poly(3-hydroxybutyrate) (PHB) has been proposed as a promising solution to fundamentally solve the disposal issue of plastic waste. PHB production techniques through fermentation of PHB-accumulating microbes such as Cupriavidus necator have been revolutionized over the past several years with the development of new strategies such as metabolic engineering. This review comprehensively summarizes the latest PHB production technologies via Cupriavidus necator fermentation. The mechanism of the biosynthesis pathway for PHB production was first assessed. PHB production efficiencies of common carbon sources, including food waste, lignocellulosic materials, glycerol, and carbon dioxide, were then summarized and critically analyzed. The key findings in enhancing strategies for PHB production in recent years, including pre-treatment methods, nutrient limitations, feeding optimization strategies, and metabolism engineering strategies, were summarized. Furthermore, technical challenges and future prospects of strategies for enhanced production efficiencies of PHB were also highlighted. Based on the overview of the current enhancing technologies, more pilot-scale and larger-scale tests are essential for future implementation of enhancing strategies in full-scale biogas plants. Critical analyses of various enhancing strategies would facilitate the establishment of more sustainable microbial fermentation systems for better waste management and greater efficiency of PHB production.

Published
2022
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9. Quantifying techno-economic indicators' impact on isolated renewable energy systems

Author

Muhammad Shahzad Javed, Tao Ma, Navid Mousavi, Salman Ahmed, Henrik Lund, Hongxing Yang, and Yanjun Dai

Subjects
Earth sciences, energy policy, energy engineering, energy systems, Science
Abstract

Summary: Addressing climate change with the rising global energy usage necessitates electricity sector decarbonization by rapidly moving toward flexible and efficient off-grid renewable energy systems (RESs). This paper analyzes the wind and solar micro-grids, with batteries and pumped hydro storage for a robust off-grid RES techno-economic operation, while considering diverse multi-objective optimization cases. This research has considered the RES variable operational losses in the developed methodology and relations between different indicators are evaluated, revealing a basic understanding between them. The results reveal that the reliability index is inversely related to the oversupply index, while directly related to the system self-sufficiency index. The cost of energy is more sensitive to technical indicators rather than the storage cost and so can be used as a primary monetary index. Energy and cost balance analysis showed that 16%–20% of the used energy was drained in RES operational losses, which were usually ignored in previous studies.

Published
2021
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10. Economic Structure Analysis Based on Neural Network and Bionic Algorithm

Author

Yanjun Dai and Lin Su

Subjects
Electronic computers. Computer science, QA75.5-76.95
Abstract

In this article, an in-depth study and analysis of economic structure are carried out using a neural network fusion release algorithm. The method system defines the weight space and structure space of neural networks from the perspective of optimization theory, proposes a bionic optimization algorithm under the weight space and structure space, and establishes a neuroevolutionary method with shallow neural network and deep neural network as the research objects. In the shallow neuroevolutionary, the improved genetic algorithm (IGA) based on elite heuristic operation and migration strategy and the improved coyote optimization algorithm (ICOA) based on adaptive influence weights are proposed, and the shallow neuroevolutionary method based on IGA and the shallow neuroevolutionary method based on ICOA are applied to the weight space of backpropagation (BP) neural networks. In deep neuroevolutionary method, the structure space of convolutional neural network is proposed to solve the search space design of neural structure search (NAS), and the GA-based deep neuroevolutionary method under the structure space of convolutional neural network is proposed to solve the problem that numerous hyperparameters and network structure parameters can produce explosive combinations when designing deep learning models. The neural network fusion bionic algorithm used has the application value of exploring the spatial structure and dynamics of the socioeconomic system, improving the perception of the socioeconomic situation, and understanding the development law of society, etc. The idea is also verifiable through the present computer technology.

Published
2021
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11. Two-Stage Fermentation of Lipomyces starkeyi for Production of Microbial Lipids and Biodiesel

Author

Le Zhang, Ee Yang Lim, Kai-Chee Loh, Yanjun Dai, and Yen Wah Tong

Subjects
two-stage fermentation, microbial lipids, biodiesel, oleaginous yeast, waste-to-resource, orange peel hydrolysate, Biology (General), QH301-705.5
Abstract

The high operating cost is currently a limitation to industrialize microbial lipids production by the yeast Lipomyces starkeyi. To explore economic fermentation technology, the two-stage fermentation of Lipomyces starkeyi using yeast extract peptone dextrose (YPD) medium, orange peel (OP) hydrolysate medium, and their mixed medium were investigated for seven days by monitoring OD600 values, pH values, cell growth status, C/N ratios, total carbon concentration, total nitrogen concentration, residual sugar concentration, lipid content, lipid titer, and fatty acids profiles of lipids. The results showed that two-stage fermentation with YPD and 50% YPD + 50% OP medium contributed to lipid accumulation, leading to larger internal lipid droplets in the yeast cells. However, the cells in pure OP hydrolysate grew abnormally, showing skinny and angular shapes. Compared to the one-stage fermentation, the two-stage fermentation enhanced lipid contents by 18.5%, 27.1%, and 21.4% in the flasks with YPD medium, OP medium, and 50%YPD + 50%OP medium, and enhanced the lipid titer by 77.8%, 13.6%, and 63.0%, respectively. The microbial lipids obtained from both one-stage and two-stage fermentation showed no significant difference in fatty acid compositions, which were mainly dominated by palmitic acid (33.36–38.43%) and oleic acid (46.6–48.12%). Hence, a mixture of commercial medium and lignocellulosic biomass hydrolysate could be a promising option to balance the operating cost and lipid production.

Published
2021
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12. Three-stage anaerobic co-digestion of food waste and horse manure

Author

Jingxin Zhang, Kai-Chee Loh, Jonathan Lee, Chi-Hwa Wang, Yanjun Dai, and Yen Wah Tong

Subjects
Medicine, Science
Abstract

Abstract A novel compact three-stage anaerobic digester (HM3) was developed to combine the advantages of high solids anaerobic digestion (AD) and wet AD for co-digestion of food waste and horse manure. By having three separate chambers in the three-stage anaerobic digester, three different functional zones were created for high-solids hydrolysis, acidogenesis and wet methanogenesis. The results showed that the functionalized partitioning in HM3 significantly accelerated the solubilization of solid organic matters and the formation of volatile fatty acids, resulting in an increase of 11~23% in methane yield. VS reduction in the HM3 presents the highest rate of 71% compared to the controls. Pyrosequencing analysis indicated that different microbial communities in terms of hydrolyzing bacteria, acidogenic bacteria and methanogenic archaea were selectively enriched in the three separate chambers of the HM3. Moreover, the abundance of the methanogenic archaea was increased by 0.8~1.28 times compared to controls.

Published
2017
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21. Practical Logic and Optimization Path of the Effectiveness of Teaching Methods in Ideological and Political Theory Courses

Author

Yu Zhao and Yanjun Dai

Subjects
General Earth and Planetary Sciences, General Environmental Science
Abstract

Since the Party Central Committee has explicitly requested the running of excellent ideological and political theory courses, the teaching methods of ideological and political theory courses have become a major topic of discussion in academic circles. A gap remains between the current teaching methods of ideological and political theory courses and those in the new era. In order to improve the nurturing effect of key courses, it is necessary to study the basic logic of its effectiveness enhancement from the perspective of practice. In the new era, it is essential to take the spirit from the series of important speeches of the Party and national leaders on ideological and political theory courses as guidance, draw on the effective teaching ideas of Comenius that reflect “fun,” “convenience,” and “thoroughness,” closely combine the teaching practice, as well as select and apply the teaching methods based on the concept of three “combinations” and two “innovations,” i.e., combining students, teachers’ teaching styles, and teaching contents; and innovating and practicing the integrated teaching method of diversified integration as well as the new teaching method of media technology-integrated smart classroom.

Published
2022
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23. STUDY ON HEAT TRANSFER CHARACTERISTICS OF FLUE GAS CONDENSATION IN NARROW GAP HEAT EXCHANGERS.

Author

Yungang WANG, Jian JIAO, Yanjun DAI, Zhiwu KE, Qinxin ZHAO, and Feixiang LI

Subjects
HEAT transfer coefficient, FLUE gases, HEAT transfer, HEATS of vaporization, WATER vapor, HEAT exchangers, CONDENSATION, HEAT convection, POLLUTION
Abstract

Flue gas after wet desulfurization contains a large quantity of water vapor, as well as a small amount of fine particulate matter, acid and other pollutants. Direct emissions will cause haze and environmental pollution. Flue gas condenser can effectively recover latent heat of vaporization and remove these pollutants. However, the traditional flue gas condenser has disadvantages such as large volume, low heat exchange efficiency and easy blockage. To overcome these problems, a new type narrow gap heat exchanger, which is easy to detach and clean, is proposed. Then, the flue gas condensation characteristic is experimentally investigated. The factors including velocity and temperature of flue gas, flow and temperature of cooling water are studied on heat transfer coefficient and the condensation rate. The results indicate that the overall heat transfer coefficient is seven times of convection heat transfer coefficient, and the condensation rate can reach more than 60%. As the cooling water temperature increases, the condensation rate and condensation heat transfer coefficient gradually decrease. With the increasing of the flue gas velocity, condensation rate gradually decreases and condensation heat transfer coefficient gradually increases. Finally, the dimensionless correlation of Nusselt number is carried out, and the error is within 10%. [ABSTRACT FROM AUTHOR]

Published
2023
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25. Experimental and theoretical assessment of a solar assisted heat pump system for in-bin grain drying: A comprehensive case study

Author

Haifeng Li, Jianguo Dai, Xinzhuang Gu, and Yanjun Dai

Subjects
Thermal efficiency, Materials science, Moisture, Renewable Energy, Sustainability and the Environment, law, Exergy efficiency, Environmental engineering, Grain drying, Water content, Bin, Operating cost, Heat pump, law.invention
Abstract

A novel solar assisted heat pump (SAHP) system for in-bin grain drying was proposed to solve the problems of poor uniformity and long drying time of grain in depot with higher initial water content in high grain piles. The effects of different operational parameters on the drying performance were numerically and experimentally investigated. The experimental results indicated that the thermal efficiency of the solar collector and the COP of the heat pump reached 63% and 5.03 under given conditions. The average heating capacity of the SAHP system was 130.2 kW, consistent with the simulation results under a typical sunny day in winter. The average water content of 3,760 tons of grain dropped from 12.9% to 12.5% after 42 h of drying. The specific moisture extraction rate of the proposed system and the exergy efficiency of the grain bin were 1.934 kg/kWh and 40.27%, respectively. The operating cost of SAHP grain drying decreased from 5.57 $/t to 1.43 $/t compared with the grain drying machine for the same drying weight. The daily drying capacity increased from 166 t/d to 334 t/d compared with the mechanical ventilation drying for the same water content reduction rate. This investigation provided guidance for expanding future researches on the SAHP system applied for in-bin grain drying.

Published
2022
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27. Gaseous production kinetics and solid structure analysis during isothermal conversion of biomass pellet under different atmospheres

Author

Zhiyi Yao, Qiang Hu, Chi-Hwa Wang, Yanjun Dai, and Xin He

Subjects
Chemical engineering, Chemistry, Yield (chemistry), Kinetics, Pellets, Biomass, Char, Activation energy, Pyrolysis, Isothermal process
Abstract

Isothermal chemical conversion of biomass pellets under the atmospheres of Ar, CO2 and O2 were conducted in this study to explore the effects of atmosphere and temperature on the gaseous releasing process and kinetics, and the structure of the solid char/ash products. Results showed that the gas production was promoted while the solid yield was decreased with the raising temperature. The CO2 reaction with char during gasification process mainly happened after 800 °C that the CO formation lasted for a longer time than pyrolysis. The surface area of char under CO2 atmosphere was increased to 215.57 m2/g with the increased temperature to 800 °C, but it was sharply reduced to 5.10 m2/g when the temperature further raising to 900 °C due to the destroyed carbon skeleton. The CO2 formation was largely promoted with a low activation energy of 11.98 kJ/mol during O2 oxidation process. Compared with the crystal structure of solid residues obtained under Ar and CO2 atmospheres, O2 oxidation process resulted in more complex crystal peaks with the main compositions of SiO2, K2SO4, and CaO. This study should be helpful to further understand the thermal conversion of biomass in a complex reaction atmosphere.

Published
2021
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28. Machine learning and circular bioeconomy: Building new resource efficiency from diverse waste streams

Author

To-Hung Tsui, Mark C.M. van Loosdrecht, Yanjun Dai, and Yen Wah Tong

Subjects
Environmental Engineering, Renewable Energy, Sustainability and the Environment, Bioengineering, General Medicine, Waste Management and Disposal
Abstract

Biorefinery systems are playing pivotal roles in the technological support of resource efficiency for circular bioeconomy. Meanwhile, artificial intelligence presents great potential in handling scientific tasks of high-dimensional complexity. This review article scrutinizes the status of machine learning (ML) applications in four critical biorefinery systems (i.e. composting, fermentation, anaerobic digestion, and thermochemical conversions) as well as their advancements against traditional modeling techniques of mechanistic approach. The contents cover their algorithm selections, modeling challenges, and prospective improvements. Perspectives are sketched to further inform collective efforts on crucial aspects. The multidisciplinary interchange of modeling knowledge will enable a more progressive digital transformation of sustainability efforts in supporting sustainable development goals.

Published
2022

29. A Multi-Scale Thermal Analysis Method for Data Centers with Application in a Ship Data Center

Author

Wen-Quan Tao, Wei Wang, Jie Zhao, Jiwei Shi, and Yanjun Dai

Subjects
Scale (ratio), business.industry, Computer science, Bipolar junction transistor, Hardware_PERFORMANCEANDRELIABILITY, Energy consumption, Insulated-gate bipolar transistor, Condensed Matter Physics, Chip, Rack, Hardware_INTEGRATEDCIRCUITS, Data center, business, Thermal analysis, Simulation
Abstract

Thermal analysis of data centers is in urgent need to ensure that computer chips remain below the critical temperature while the energy consumption for cooling can be reduced. It is difficult to obtain detailed hotspot locations and temperatures of chips in large data centers containing hundreds of racks or more by direct measurement. In this paper, a multi-scale thermal analysis method is proposed that can predict the temperature distribution of chips and solder balls in data centers. The multi-scale model is divided into six scales: room, rack, server, Insulated-Gate Bipolar Transistor (IGBT), chip and solder ball. A concept of sub-model is proposed and the six levels are organized into four simulation sub-models. Sub-model 1 contains Room, Rack and Server (RRS); Sub-model 2 contains Server and IGBT (SI); Sub-model 3 contains IGBT and Chip (IC), and Sub-model 4 contains Chip and Solder-ball (CS). These four sub-models are one-way coupled by transmitting their results as boundary conditions between levels. The full-field simulation method is employed to verify the efficiency and accuracy of multi-scale simulation method for a single-rack data center. The two simulation results show that the highest temperature emerges in the same location. The Single-rack Full-field Model (SRFFM) costs 2.5 times more computational time than that with Single-rack Multi-scale Model (SRMSM). The deviation of the highest temperature of chips and solder balls are 1.57°C and 0.2°C between the two models which indicates that the multi-scale simulation method has good prospect in the data center thermal simulation. Finally, the multi-scale thermal analysis method is applied to a ship data center with 15 racks.

Published
2021
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30. High-Efficiency, Mass-Producible, and Colored Solar Photovoltaics Enabled by Self-Assembled Photonic Glass

Author

Zhenpeng Li, Tao Ma, Senji Li, Wenbo Gu, Lin Lu, Hongxing Yang, Yanjun Dai, and Ruzhu Wang

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

Building-integrated photovoltaics is a crucial technology for developing zero-energy buildings and sustainable cities, while great efforts are required to make photovoltaic (PV) panels aesthetically pleasing. This places an urgent demand on PV colorization technology that has a low impact on power conversion efficiency (PCE) and is simultaneously mass-producible at a low cost. To address this challenge, this study contributes a colorization strategy for solar PVs based on short-range correlated dielectric microspheres

Published
2022

31. Developments of CPC solar evacuated glass tube collector with a novel selective coating

Author

Guangbai Ma, Zhiqiang Yin, Jing Qi, Yanjun Dai, and Xijie Liu

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, 020209 energy, food and beverages, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Fin (extended surface), stomatognathic diseases, Coating, Getter, Thermal, otorhinolaryngologic diseases, 0202 electrical engineering, electronic engineering, information engineering, engineering, General Materials Science, Thermal emittance, Tube (fluid conveyance), Composite material, 0210 nano-technology, Layer (electronics), Glass tube
Abstract

This paper describes the development of a novel CPC (compound parabolic collector) evacuated tube solar collector, using a medium-temperature selective coating. The medium-temperature selective coating was obtained by co-sputtering titanium and aluminum targets. The absorptance and the thermal emittance of the heat treated coating is 0.95, and 0.04 at 80℃ respectively. The collector was optimized, using a manifold of copper U-tube with anti-oxidized coating and aluminum fin. An anti-reflection layer is added on the cover glass tube, and non-flash getter are used for maintaining the vacuum of the collector tubes. Thermal test results shown that the instantaneous efficiency based on gross area ηG can reach 0.46 at the temperature of 150℃ and the normalized temperature difference Tm* is 0.13 [(m2-°C)/W]. The experimental steam system application showed that the novel CPC solar collector can produce steam from water with temperatures about 108–145 °C during sunny days. It was also shown that the thermal performance of the solar collector did not degraded significantly.

Published
2021
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32. Heat transfer analysis and thermal performance investigation on an evacuated tube solar collector with inner concentrating by reflective coating

Author

Yao Zhao, Jian Yao, Yuan-Ching Chiang, Chai Shaowei, Jyun-De Liang, Yanjun Dai, and Sih-Li Chen

Subjects
Evacuated tube, Thermal efficiency, Materials science, Renewable Energy, Sustainability and the Environment, 020209 energy, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Coating, Thermal, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, engineering, General Materials Science, Irradiation, Composite material, 0210 nano-technology, Thermal analysis, Glass tube
Abstract

Evacuated tube solar collector (ETSC) is widely used for domestic and industrial applications. Using reflective coating in an ETSC to realize concentration is a method to heighten the thermal efficiency due to solar irradiation could be reflected by the coating on the lower half of the outer glass tube and concentrated to the eccentric inner absorber. In this paper, an evacuated tube solar collector with inner concentrating (ETSC-IC) by reflective coating was proposed and fabricated. A series of experimental tests of the ETSC-IC was conducted to investigate the thermal performance. In addition, the mathematical model of the novel collector with inner concentrating was developed, and the structural parameters of the inner reflective concentrating evacuated tube, including the coating angel and the eccentric distance, have been analyzed. The optical and thermal analysis revealed that the best coating angle of the evacuated tube was 180°, and the thermal performance of the ETSC-IC enhanced with the increase of the eccentric distance under the best coating angle. The thermal efficiency of the ETSC-IC could reach 0.65 to 0.72 on the condition that the solar irradiation was around 950 W/m2 and the temperature of inlet water varied between 45 °C and 70 °C, and the ambient temperature was 31.2 °C. The thermal efficiency of the ETSC-IC was improved by approximately 10% compared with the conventional evacuated tube due to the enhanced irradiation concentrating and the reduction of heat loss caused by the coating on the outer glass tube.

Published
2021
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34. Meeting the heavy-metal safety requirements for food crops by using biochar: An investigation using sunflower as a representative plant under different atmospheric CO2 concentrations

Author

Yiying Wang, Guiying Lin, Xian Li, Ming Hang Tai, Shuang Song, Hugh Tiang Wah Tan, Ken Leong, Elvis Yew Boon Yip, Grace Yoke Chin Lee, Yanjun Dai, and Chi-Hwa Wang

Subjects
Environmental Engineering, Environmental Chemistry, Pollution, Waste Management and Disposal
Published
2023
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35. Experiment investigation on a LiBr-H2O concentration difference cold storage system driven by vapor compression heat pump

Author

Yanjun Dai, Jinfeng Chen, Wang Hailiang, Haiquan Sun, Peng Chu, and Wang Hongbin

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, Nuclear engineering, Heat pump and refrigeration cycle, Cold storage, Coefficient of performance, Energy storage, law.invention, law, General Materials Science, Condenser (heat transfer), Circulating pump, Evaporator, Heat pump
Abstract

Solar-powered LiBr absorption cooling system is of potential in the application of air-conditioning. A LiBr-H2O concentration difference cold storage system driven by vapor compression heat pump was proposed. This cold storage process is not affected by the environmental conditions, since the main energy input is low price electricity at night. The experimental results show that the energy storage density (ESD) can reach 77.8 kWh/m3 and the energy storage coefficient of performance (ESCOP) is 2.81 with low heat loss. The ESCOP means the energy stored in the cold storage process divided by the total electricity consumption in the absorption and heat pump subsystem. The heat transfer in the condenser of the absorption subsystem approximately equals that in the evaporator of the heat pump, and the electricity consumption of the circulating pump in the absorption subsystem is low. Therefore, the value of ESCOP should be slightly lower than the COP of the heat pump system but for higher than 1. These results indicate the feasibility of improving the system efficiency, the operation cost, and long term operation of the solar air conditioning system by coupling the absorption and vapor compression cooling cycles. Finally, the influence of working parameters on the system performance is discussed based on the experimental and simulation analyses. The energy balance between the absorption cycle and the heat pump cycle in the cold storage system is analyzed. It is found that the coefficient of performance of the heat pump (COPele,HP) and ESCOP increase with a low initial LiBr-H2O solution concentration. The ESCOP decreases by 34.4% when the initial concentration increases from 52% to 57%. The average ESD increases to 140.2 kWh/m3 with a concentration difference of 8%. Based on the experiment results, the payback period of the proposed system is estimated as 2.4 years comparing with the traditional LiBr-H2O absorption system.

Published
2021
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36. Performance analysis of a residential heating system using borehole heat exchanger coupled with solar assisted PV/T heat pump

Author

Yanjun Dai, Ming Jun Huang, Binshou Tian, Jian Yao, Lu Zhang, and Wenjie Liu

Subjects
Materials science, 060102 archaeology, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Geothermal energy, Nuclear engineering, Photovoltaic system, 06 humanities and the arts, 02 engineering and technology, Solar energy, law.invention, Heating system, law, Thermal, Heat exchanger, 0202 electrical engineering, electronic engineering, information engineering, Mass flow rate, 0601 history and archaeology, business, Heat pump
Abstract

Borehole heat exchanger (BHE) is a promising method for extracting heat from the deep geothermal energy which has been widely used for residential heating in high latitude areas. The solar assisted photovoltaic/thermal (PV/T) heat pump could convert solar energy into useful heat efficiently, and could be further used to heat water from the BHE to a higher temperature level. In this paper, a residential heating system using BHE coupled with solar assisted PV/T heat pump is therefore proposed with further performance analysis. The simulation results show that a larger mass flow rate could increase the BHE's heat extract capacity but also increase the flow resistance and pump power under nominal conditions. The circulating water would not extract heat from rock-soil if the inlet temperature exceeds 48.5 °C when mass flow rate is 12 kg/s. Furthermore, the maximum water temperature from this hybrid system could reach 40.8 °C while the solar fraction is 67.5% when the area of PV/T module is 1000 m2, solar irradiation is 600 W/m2 and depth of the BHE is 2500 m. In the meantime, the heating COP of this hybrid system could reach 7.4 and the system could operate independently without power input from electrical grid.

Published
2020
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37. A 28 kWe multi-source high-flux solar simulator: Design, characterization, and modeling

Author

Wojciech Lipiński, Xian Li, Yanjun Dai, Chi-Hwa Wang, and Jialing Chen

Subjects
Physics, CMOS sensor, Renewable Energy, Sustainability and the Environment, HFSS, business.industry, 020209 energy, Monte Carlo method, Reflector (antenna), 02 engineering and technology, Radius, 021001 nanoscience & nanotechnology, Optics, 0202 electrical engineering, electronic engineering, information engineering, Calibration, Radiative transfer, General Materials Science, Solar simulator, 0210 nano-technology, business
Abstract

Singapore’s first multi-source high-flux solar simulator (HFSS) that comprises an array of seven 4-kWe xenon short-arc lamps close-coupled with ellipsoidal reflectors is designed, constructed, and characterized. An indirect mapping system that consists of a water-cooled Lambertian target, a CMOS camera, and a heat-flux gauge is adopted herein to experimentally characterize the performance of the developed HFSS. A calibration constant of 192.8 ± 9.6 kW m−2 (GS µs−1)–1 is determined and used to transform the raw-flux maps with grayscale values to the absolute-flux maps. Utilizing a series of flexible and precise adjusters, the variability of ± 1 mm in the x- and y-directions of the peak flux points of the radiation modules is measured. A peak flux of 7740 kW m−2 is measured for the sum of all 7 radiation modules. Average radiative fluxes of 4191 kW m−2 and 2933 kW m−2 can be observed from circular target areas of O40 mm and O60 mm, respectively, associated with promising electricity-to-target transfer efficiencies of 18.8% and 29.6%. A Monte Carlo ray-tracing (MCRT) model is calibrated by the experimental data. Based on the minimum root-mean-standard deviation between the measured and simulated results of the radiative power on the target, the optimal parameters of the MCRT model include the arc radius of 3.4 mm and the reflector surface error of 1.1 mrad.

Published
2020
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38. Theoretical analysis on efficiency factor of direct expansion PVT module for heat pump application

Author

Jian Yao, Yanjun Dai, Ming Jun Huang, and Erjian Chen

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Nuclear engineering, Photovoltaic system, Energy conversion efficiency, 02 engineering and technology, 021001 nanoscience & nanotechnology, Solar energy, law.invention, Efficiency factor, law, Thermal, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Distribution uniformity, 0210 nano-technology, business, Evaporator, Heat pump
Abstract

Direct expansion solar assisted PVT (photovoltaic/thermal) heat pump is a combination of PVT technology and heat pump technology, which can improve the comprehensive conversion efficiency of solar energy, and it is suitable for solar heating applications. In this paper, the efficiency factor of direct expansion PVT module employing roll-bond panel has been theoretically derived, modified, and validated by experimental results. Moreover, the efficiency factor could be used to design, evaluate, and optimize the thermal performance of direct expansion solar assisted heat pump systems. In addition, parameter analysis of four evaporator unit types has been conducted, and the recommendation values of each parameter have also been presented. The simulation results show that the roll-bond evaporator (fluid channel width: 10 mm) with hexagon and rectangle patterns have better temperature distribution uniformity than grid and linear types, and their temperature differences are both 0.038 °C while their dimensionless pressure losses are 0.109 and 0.230, respectively. To specifically design different kinds of PVT collector/evaporator or direct expansion evaporators, a novel design method for roll-bond evaporator is proposed, and a combination of hexagon and grid types is recommended for PVT module. Moreover, the recommendation fluid channel width of the roll-bond panel is 8 mm to 13 mm while the scaling ratio is 0.8 to 1.2. The modified efficiency factors are 0.521, 0.564, 0.549, and 0.342 of hexagon, grid, rectangle, and linear types when the fluid channel width is 10 mm, respectively.

Published
2020
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39. Proposal and performance analysis of a novel solar-assisted resorption-subcooled compression hybrid heat pump system for space heating in cold climate condition

Author

Yanjun Dai, Peng Chu, Teng Jia, and Pengbo Dou

Subjects
Materials science, 060102 archaeology, Renewable Energy, Sustainability and the Environment, 020209 energy, Nuclear engineering, Hybrid heat, 06 humanities and the arts, 02 engineering and technology, Coefficient of performance, law.invention, Lift (force), Subcooling, law, Hybrid system, 0202 electrical engineering, electronic engineering, information engineering, 0601 history and archaeology, Absorption heat pump, Vapor-compression refrigeration, Heat pump
Abstract

Absorption-resorption heat pumps (ARHPs) can efficiently utilize low-temperature solar heat for winter space heating, but are restricted by the relatively weak low ambient temperature adaptability. By combining the different strengthens of vapor compression heat pump (VCHP) and absorption-resorption heat pump (ARHP), a novel solar-assisted resorption-subcooled compression hybrid heat pump system with higher heating capacity under cold climate condition for space heating is proposed. Thermodynamic models for the hybrid system involving two subsystems are developed for performance evaluation under different operation conditions. Feasible high pressure/low pressure (PH/PL) and evaporation temperature/condensation temperature (Te/Ta) ranges for the hybrid system are revealed for component design. Based on that, performance evaluation indices like total coefficient of performance (COPtot), primary energy ratio (PER), primary energy saving ratio (PESR), coefficient from solar irradiation to heating capacity (SCOP) are investigated in terms of different PH/PL and Te/Ta values. The results showed that for the base-case, the above indices are 2.41, 1.66, 0.35 and 1.21, respectively. In addition, heat source temperature demand, heating capacity and ambient air temperature need of the hybrid system are compared with those of the conventional absorption heat pump (AHP), single ARHP and single VCHP under the same operation conditions. The results show that the hybrid system can extend the operation heat source temperature to above 72 °C, highlighting the possibility of integrating with common non-tracking solar collectors, and can extend the feasible ambient air temperature to above −20 °C. Moreover, by recovering the sub-cooling heat of VCHP subsystem for ARHP subsystem operation, the hybrid system can lift the heating capacity by over 50% based on the equivalent VCHP system.

Published
2020
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40. Theoretical and experimental investigation on a GAX-Based NH3-H2O absorption heat pump driven by parabolic trough solar collector

Author

Teng Jia, Yanjun Dai, and Enqian Dai

Subjects
Thermal efficiency, Work (thermodynamics), Materials science, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Solar energy, law.invention, Volumetric flow rate, law, Heat exchanger, 0202 electrical engineering, electronic engineering, information engineering, Parabolic trough, General Materials Science, Absorption heat pump, 0210 nano-technology, business, Heat pump
Abstract

This research involves a GAX-based ammonia-water absorption heat pump, which utilizes solar energy and natural gas as heat source. The experiments of parabolic tough collector and GAX absorption heat pump were carried out separately. GAX absorption heat pump is operated when the ambient temperature is 4.31–11.07 °C, COP approaches 1.44–1.66. Thermal efficiency of the PTC varies from 0.50 to 0.60. A mathematical model of the coupled solar absorption heat pump is built. The effect of each heat exchanger size on the GAX cycle performance is investigated, results show that the heat exchanger size of solution cooled absorber has the greatest impact on the cycle. Both Solar driven mode and Solar-NG driven mode were studied. Solar driven mode is strict with solar energy, if the direct normal irradiance is below 560 W/m2 the system cannot work. Solar-NG driven mode could work under any solar radiation condition. In this mode, generation temperature could be controlled by changing the flow rate of natural gas. The optimal generation temperature is found to be around 180 °C when Tamb = 7 °C, DNI = 800 W/m2, Twout = 45 °C. Besides, system analysis reveals that the heat pump could perform competitive in low ambient temperature if the solar radiation is abundant, which makes Lhasa a perfect site for the system. Economic analysis in Lhasa show that the addition of solar collector could reduce the operating cost by more than 25%.

Published
2020
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41. Performance analysis of solar assisted heat pump coupled with build-in PCM heat storage based on PV/T panel

Author

Ming Jun Huang, Jian Yao, Yanjun Dai, and Hui Xu

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Nuclear engineering, Photovoltaic system, 02 engineering and technology, Coefficient of performance, 021001 nanoscience & nanotechnology, Solar energy, Thermal energy storage, Phase-change material, law.invention, law, Underfloor heating, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, 0210 nano-technology, business, Evaporator, Heat pump
Abstract

PV/T (photovoltaic/thermal) technology is a combination of PV module (photovoltaic utilization) and collector (photothermal utilization), which can improve the comprehensive utilization efficiency of solar energy and has a broad application prospect. In this paper, PV/T module is coupled with heat pump evaporator to form a direct-expansion solar PV/T heat pump which is suitable for heat application in high latitude area. To achieve stable residential heating, a solar PV/T heat pump system coupled with build-in PCM (phase change material) heat storage is therefore proposed and simulated. Meanwhile, the mathematical model of solar PV/T heat pump coupled with build-in PCM heat storage system is established and verified. The simulation results show that the temperature of underfloor heating which using build-in PCM heat storage can reach 22–31 °C after 39 h when the circulating water is 40 °C. Moreover, the heating COP (Coefficient of Performance) increases with the increase of solar radiation, ambient temperature and area of PV/T collector, and decrease of wind speed, respectively. A 20 m2 PV/T panel module can output 21.4% of the electricity to power grid when the solar radiation intensity is 600 W/m2 and meet the heat demand of a 100 m2 room while maintain the operation of the system. Meanwhile, the heating COP can reach 5.79 which is 70% higher than the conventional air conditioning system and the electrical, thermal, overall efficiencies are 17.77%, 55.76% and 75.49%, respectively.

Published
2020
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42. Influence of impeller’s geometric parameters on refrigerant flow and thermal performance of a working fluid pump

Author

Hui-Fan Zheng, Yonggao Yin, Xin Xin, Yanjun Dai, Yongchang Wang, Yuan-Qing Ma, and Xuelai Zhang

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, lcsh:Mechanical engineering and machinery, Flow (psychology), flow performance, Mechanics, orthogonal analysis, Refrigerant, Physics::Fluid Dynamics, working fluid pump, Impeller, ejector refrigeration, Thermal, Working fluid, lcsh:TJ1-1570, thermal performance
Abstract

In this paper, the refrigerant flow and the thermal performance of a working fluid pump are performed in the perspective of an ejector refrigeration system. The influence of impeller?s geometric parameters on the internal pressure, flow rate and cavitation of the pump is studied experimentally and numerically. A vertical multi-stage centrifugal pump is selected as an experimental prototype for numerical verification, and a working fluid pump, which is optimized by the orthogonal analysis, is numerically studied, the results show that the optimized one has better thermal performance than the prototype.

Published
2020

43. Meeting the Heavy Metal Safety Requirements for Food Crops by Using Biochar: An Investigation by Using Sunflower as a Representative Plant Under Different Atmospheric Co2 Concentrations

Author

Yiying Wang, Guiying Lin, Xian Li, Ming Hang Tai, Shuang Song, Hugh Tiang Wah Tan, Ken Leong, Elvis Yip Yew Boon, Grace Lee Yoke Chin, Yanjun Dai, and Chi-Hwa Wang

Subjects
History, Polymers and Plastics, Business and International Management, Industrial and Manufacturing Engineering
Published
2022
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