Your search keyword '"Rujing Yan"' showing total 14 results

1. Thermodynamic analysis of fuel cell combined cooling heating and power system integrated with solar reforming of natural gas

Author

Chaofan Ma, Youliang Cheng, Rujing Yan, Jiangjiang Wang, and Tong Yu

Subjects

Chiller, Exergy, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Fossil fuel, 02 engineering and technology, 021001 nanoscience & nanotechnology, Solar energy, Natural gas, Distributed generation, 0202 electrical engineering, electronic engineering, information engineering, Exergy efficiency, Environmental science, General Materials Science, 0210 nano-technology, business, Process engineering, Syngas

Abstract

Hybrid natural gas combined cooling, heating, and power (CCHP) systems integrated with solar technologies offer the efficient use of distributed energy resources for reducing the use of fossil fuels and greenhouse gas emissions. This paper proposes a novel CCHP system, using the phosphoric acid fuel cell (PAFC) as the prime mover, integrated with the natural gas reforming with solar energy assistance. Their respective thermodynamic models are constructed for simulation of the system thermodynamic performance. The simulation results demonstrate that the energy efficiencies of the hybrid system with solar energy assistance are 55.12% for the heater mode and 66.77% for the chiller mode, while the exergy efficiencies are 32.87% and 31.59%, respectively. Similarly, when solar energy is not available, its energy efficiencies are 59.24% and 69.18%, while its exergy efficiencies are 40.09% and 39.01%, respectively. In the PAFC–CCHP hybrid system, the exergy efficiencies are key components in the overall efficiency, and the efficiencies with and without solar energy are 29.34% and 36.95%, respectively. Solar energy and exergy share is employed to analyze the solar energy contribution, and they are 36.1% and 35.6%, respectively. Meanwhile, the parametric analysis is also carried out to evaluate the effects of key parameters on the performance. The results show that increasing the reforming temperature, influenced by solar energy, improves the natural gas conversion and boosts the hydrogen concentration of the syngas fed into the PAFC, which increases the overall exergy efficiency. However, the effect of the reforming temperature is reduced when the reforming temperature is higher than 1073.15 K.

Published

2020

2. Comparative study for four technologies on flexibility improvement and renewable energy accommodation of combined heat and power system

Author

Rujing Yan, Jiangjiang Wang, Shuojie Huo, Jing Zhang, Saiqiu Tang, and Mei Yang

Subjects

General Energy, Mechanical Engineering, Building and Construction, Electrical and Electronic Engineering, Pollution, Industrial and Manufacturing Engineering, Civil and Structural Engineering

Published

2023

3. Flexibility improvement and stochastic multi-scenario hybrid optimization for an integrated energy system with high-proportion renewable energy

Author

Rujing Yan, Jiangjiang Wang, Shuojie Huo, Yanbo Qin, Jing Zhang, Saiqiu Tang, Yuwei Wang, Yan Liu, and Lin Zhou

Subjects

General Energy, Mechanical Engineering, Building and Construction, Electrical and Electronic Engineering, Pollution, Industrial and Manufacturing Engineering, Civil and Structural Engineering

Published

2023

4. Leveraging heat accumulation of district heating network to improve performances of integrated energy system under source-load uncertainties

Author

Jiangjiang Wang, Shuojie Huo, Rujing Yan, and Zhiheng Cui

Subjects

General Energy, Mechanical Engineering, Building and Construction, Electrical and Electronic Engineering, Pollution, Industrial and Manufacturing Engineering, Civil and Structural Engineering

Published

2022

5. A two-stage stochastic-robust optimization for a hybrid renewable energy CCHP system considering multiple scenario-interval uncertainties

Author

Rujing Yan, Jiangjiang Wang, Jiahao Wang, Lei Tian, Saiqiu Tang, Yuwei Wang, Jing Zhang, Youliang Cheng, and Yuan Li

Subjects

General Energy, Mechanical Engineering, Building and Construction, Electrical and Electronic Engineering, Pollution, Industrial and Manufacturing Engineering, Civil and Structural Engineering

Published

2022

6. Thermodynamic analysis of fuel-cell-based combined cooling, heating, and power system integrated solar energy and chemical looping hydrogen generation

Author

Zherui Ma, Fuxiang Dong, Lei Tian, Rujing Yan, Zepeng Han, Jiangjiang Wang, and Zhanwei Liang

Subjects

Exergy, Materials science, business.industry, Mechanical Engineering, Nuclear engineering, Building and Construction, Energy consumption, Solar energy, Pollution, Industrial and Manufacturing Engineering, General Energy, Electricity generation, Exergy efficiency, Electrical and Electronic Engineering, business, Chemical looping combustion, Civil and Structural Engineering, Hydrogen production, Efficient energy use

Abstract

A novel solid-oxide-fuel-cell-based cooling, heating, and power (CCHP) system integrated chemical looping hydrogen generation is proposed, in which the chemical looping hydrogen generation realizes the high-efficiency CO2 capture and provides hydrogen to fuel cell, avoiding carbon deposition caused by the direct reaction of methane. The high-temperature solar heat collector is integrated to assist the fuel cell subsystem in achieving high-efficiency power generation and energy cascade utilization. The thermodynamic models of components are constructed, and the energy and exergy performances under the design conditions with or without solar energy are compared and analyzed. Through validating the thermodynamic models, the simulation results indicate that the energy and exergy efficiencies in cooling mode are 78.02% and 45.92%, respectively. The energy efficiency in heating mode reduces by 5.08%, while the exergy efficiency increases by 0.67%. The CO2 capture rate of the proposed system reaches 99.96% and the CO2 purity is about 99.59%. The energy consumption of CO2 capture in the proposed system reduces by 69.37% compared to the conventional system. The sensitivity analysis of key parameters such as fuel cell operating temperature and direct normal irradiance on system performances are performed. The results show the total energy and exergy efficiencies can be improved by properly increasing the SOFC operating temperature. Although the energy and exergy efficiencies slowly drop with the increasing direct normal irradiation, the energy output increases by 6.10% and 4.95% in cooling and heating mode from 500 W/m2 to 1000 W/m2, respectively.

Published

2022

7. Multi-objective optimization with thermodynamic analysis of an integrated energy system based on biomass and solar energies

Author

Zherui Ma, Fuxiang Dong, Rujing Yan, Haiyue Chen, and Jiangjiang Wang

Subjects

Primary energy, Renewable Energy, Sustainability and the Environment, business.industry, Strategy and Management, Photovoltaic system, Building and Construction, Thermal energy storage, Multi-objective optimization, Industrial and Manufacturing Engineering, law.invention, Renewable energy, Internal combustion engine, law, Exergy efficiency, Environmental science, Process engineering, business, General Environmental Science, Heat pump

Abstract

The integrated energy system (IES) can effectively utilize the distributed renewable energies, but its performance improvement requires advanced design and optimization methods. This study proposes a new IES based on biomass gasification integrated with an internal combustion engine, photovoltaic and solar collectors, an absorption chiller/heater, a heat pump and a thermal storage unit to utilize renewable energies effectively. Based on the thermodynamic models of components considering off-design conditions, a multi-objective optimization model of biomass IES is established to improve the comprehensive performances of energy, economy, and environment. A decision method is proposed to select the optimal configuration considering the Euclidean distance between the Pareto solution and the ideal solution. The results demonstrate that in the specific case, the capacity of the internal combustion engine with biomass gasification is preferred to be low, and 71.4% of Pareto solutions is less than 200 kW during the set range from 20 to 1,000 kW. The larger capacity of solar photovoltaic panels achieves more benefits than solar heat collectors. Moreover, the optimal IES determined by the minimum Euclidean distance has primary energy utilization efficiency of 43.4% and exergy efficiency of 18.0%, which saves primary energy of 7.1%, the annual total cost of 7.2%, and reduces carbon dioxide emission by 41.5%.

Published

2021

8. Incorporating deep learning of load predictions to enhance the optimal active energy management of combined cooling, heating and power system

Author

Rujing Yan, Jiangjiang Wang, Yi Liu, Yanpeng Ma, and Yuan Zhou

Subjects

Artificial neural network, Linear programming, Energy management, Computer science, 020209 energy, Mechanical Engineering, 02 engineering and technology, Building and Construction, Pollution, Industrial and Manufacturing Engineering, Energy storage, Dynamic programming, Electric power system, Model predictive control, General Energy, 020401 chemical engineering, Control theory, Genetic algorithm, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Electrical and Electronic Engineering, Civil and Structural Engineering

Abstract

The energy management of combined cooling, heating and power (CCHP) system is essential for simultaneously improving its energy and economic performances. However, the conventional operation strategies are mainly logical control, which passively adapts to users’ demands. This paper proposes an optimal economic energy dispatch model of the CCHP system incorporating deep learning of load predictions to fulfill active control strategy in dynamic programming. A cross linear optimization method with a half update strategy of component efficiencies is developed to solve and calculate the variable component efficiencies in the CCHP system. Compared to the genetic algorithm, the proposed method achieves better results and the convergence time is reduced by 93%. The model predictive control of the CCHP system in load predictions of an artificial neural network is combined to the dynamic programming to realize the active energy dispatch strategy. The effects of short-term prediction and long-term prediction on forecast performances and operation costs are discussed. The case study demonstrates that the ideal prediction horizon of 8 h is recommended to fully realize the active functions of energy storage devices in the CCHP system. The proposed active strategy with model predictive control reduces the operational cost by 3.66% compared to the passive control strategy.

Published

2021

9. Multi-objective optimization of combined cooling, heating and power system considering the collaboration of thermal energy storage with load uncertainties

Author

Rujing Yan, Chunyan Lu, and Jiangjiang Wang

Subjects

Electric power system, Renewable Energy, Sustainability and the Environment, Total cost, Computer science, Reliability (computer networking), Energy Engineering and Power Technology, Electrical and Electronic Engineering, Thermal energy storage, Multi-objective optimization, Energy storage, Automotive engineering, Waste heat recovery unit, Power (physics)

Abstract

A thermoelectric coupling limitation imposes the combined cooling, heating, and power (CCHP) systems low performance under dynamic uncertainty. Energy storage is an effective way to address the problem. This paper integrates an energy storage device into the CCHP system to decouple the limitation and proposes a multi-objective optimization model considering load uncertainty for the optimal capacity of energy storage. The design space is a set of all feasible configuration schemes that meet the requirements of the system’s confidence level. A chance-constrained method is employed to address the load uncertainty and transform the uncertain optimization into deterministic optimization. Load uncertainty is closely related to the given confidence level. Therefore, the indicator loss of load expectation is used to evaluate the reliability of the CCHP system. The economic and environmental performance of the CCHP system is assessed by using the annual total cost and carbon dioxide emission, respectively. A hotel example validates the feasibility of the proposed methodology. The results show that increasing the confidence level from 0.5 to 0.99 results in the capacity increase of the waste heat boiler from 326.8 kW to 408.2 kW in the heating mode. The increased change reduces the loss of load expectation by 108.4% and increases the annual operation cost by 110.14%.

Published

2021

10. Stochastic multi-scenario optimization for a hybrid combined cooling, heating and power system considering multi-criteria

Author

Yuanjuan Yang, Dexiu Huang, Jiangjiang Wang, Rujing Yan, Zherui Lu, Haiyue Chen, and Jiahao Wang

Subjects

Mathematical optimization, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Energy Engineering and Power Technology, 02 engineering and technology, Grid, Renewable energy, Nameplate capacity, Electric power system, Fuel Technology, 020401 chemical engineering, Nuclear Energy and Engineering, Hybrid system, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Scenario optimization, Energy supply, 0204 chemical engineering, business, Efficient energy use

Abstract

Combined cooling, heating and power (CCHP) system integrated with multiple renewable energies can improve the environmental performance while increasing the dependency on the national grid due to the multiple uncertainties. This paper proposes a multi-objective stochastic multi-scenario optimization method for the optimal capacity of a CCHP system integrated wind, solar and geothermal energy considering its energy supply independence, environmental impact, economic performance and energy efficiency. The spatiotemporal multiple uncertainties in wind velocity, solar irradiation and multiple loads are characterized by the stochastic multi-scenarios generated by the stochastic hierarchy scenario-generation method. The hybrid system's flexibility is evaluated by both the grid integration level and net interaction level. The environmental performance is assessed by both the carbon emission reduction rate and renewable energy penetration. The economic and energy performances are characterized by the annual cost-saving rate and primary energy-saving rate, respectively. The multi-objective stochastic optimal design method is formulated and solved using non-dominated sorting genetic algorithm II. The case study results show that there are slight deviations of objectives between the stochastic multi-scenario and traditional optimizations, while the former can save 58.69% computation time. Moreover, the installed capacity increase of the electrical energy storage to 870kWh can reduce the system's dependency on the national grid and the net interaction level to 3.74% while deteriorating the economic performance and dropping the annual cost-saving rate to −217.37%. Inversely, the installed capacity increase of renewable energy generators can enhance economic and environmental performances while worsening the net interaction level.

Published

2021

11. Multi-objective two-stage adaptive robust planning method for an integrated energy system considering load uncertainty

Author

Youliang Cheng, Rujing Yan, Lidong Zhang, Jiangjiang Wang, Shuaikang Lu, Yuan Zhou, and Zherui Ma

Subjects

Flexibility (engineering), Mathematical optimization, Computer science, 020209 energy, Mechanical Engineering, 0211 other engineering and technologies, Robust optimization, 02 engineering and technology, Building and Construction, Grid, Fuzzy logic, 021105 building & construction, 0202 electrical engineering, electronic engineering, information engineering, Energy transformation, Electrical and Electronic Engineering, Cluster analysis, Decision model, Energy (signal processing), Civil and Structural Engineering

Abstract

An integrated energy system (IES) is considered as an effective approach to reduce carbon emissions, lower energy supply costs and increase system flexibility. As numerous energy conversion and storage devices with various features have been developed, determining their types and capacity size and optimizing the synergic action of all selected energy devices under load uncertainty have become challenging issues during the planning and designing of a new IES. To address these issues, a load uncertainty model is constructed by integrating the regional equivalent standard building-integrated load prediction method, the robust uncertainty set method and the fuzzy C-means clustering algorithm. Based on this uncertainty model, this paper proposes a planning method that incorporates the fuzzy multi-objective decision and two-stage adaptive robust optimization methods for handling these challenging issues. The multi-objective decision method enables comprehensive optimization based on the system's economic performance, carbon emissions and grid integration level. The two-stage adaptive robust optimization method aims to optimize the single-objective problem transformed by the multi-objective decision method. The planning method is implemented in an industrial park in the Baoding City of China. The influence of load budget uncertainty, annual load growth rate and energy purchase price is then investigated. The results show that the load budget uncertainty and annual load growth rate only affect the optimal capacity size of the selected devices, whereas the energy purchase price influences both the optimal device types and their capacity size. The optimal capacity size remains constant when the load budget uncertainty exceeds 3. This study provides a methodology to select the suitable device types and determine their capacity size for IES under load uncertainty, which will benefit the design of a new IES.

Published

2021

12. Application of hybrid model based on double decomposition, error correction and deep learning in short-term wind speed prediction

Author

Zherui Ma, Jiandong Jia, Wenliang Xu, Xin Yang, Rujing Yan, Hongwei Chen, and Jiangjiang Wang

Subjects

Wind power, Artificial neural network, Renewable Energy, Sustainability and the Environment, business.industry, Computer science, 020209 energy, Deep learning, Energy Engineering and Power Technology, 02 engineering and technology, Hilbert–Huang transform, Wind speed, Term (time), Noise, Fuel Technology, 020401 chemical engineering, Nuclear Energy and Engineering, Control theory, 0202 electrical engineering, electronic engineering, information engineering, Artificial intelligence, 0204 chemical engineering, Error detection and correction, business

Abstract

As wind power accounts for an increasing proportion of the electricity market, the wind speed prediction plays a vital role in the stable operation of the power grid. However, owing to the stochastic nature of wind speed, predicting wind speeds accurately is difficult. Aims at this challenge, a new short-term wind speed prediction model based on double decomposition, error correction strategy and deep learning algorithm is proposed. The complete ensemble empirical mode decomposition with adaptive noise and variational mode decomposition are applied to decompose the original wind speed series and error series, respectively. The deep learning algorithm based on long short term memory neural network, is utilized to detect the long-term and short-term memory characteristics and build the suitable prediction model for each sub-series. In the four real forecasting cases, nine models were built to compare the performance of the proposed model. The experimental results show that the proposed model performs better than all other considered models without double decomposition, and the variational mode decomposition for error series can improve the effect of error correction strategy.

Published

2020

13. Novel planning methodology for energy stations and networks in regional integrated energy systems

Author

Yi Liu, Youliang Cheng, Rujing Yan, Jiangjiang Wang, Sitong Zhu, and Zherui Ma

Subjects

Imagination, Mathematical optimization, Renewable Energy, Sustainability and the Environment, Computer science, 020209 energy, media_common.quotation_subject, Kernel density estimation, Energy Engineering and Power Technology, 02 engineering and technology, Energy consumption, Network planning and design, Fuel Technology, 020401 chemical engineering, Nuclear Energy and Engineering, Search algorithm, Shortest path problem, 0202 electrical engineering, electronic engineering, information engineering, Energy supply, 0204 chemical engineering, Energy (signal processing), media_common

Abstract

The effective planning of energy stations and networks is critical for improving the economic and energy performance of regional integrated energy systems. Based on the principle of minimizing investment cost and network losses, this study proposes a novel methodology involving both kernel density estimation and shortest path methods to optimize the transmission network. The optimal locations of energy supply and storage stations are determined according to the kernel density of the annual energy consumption of building groups and the annual energy output of energy stations in the kernel density estimation method, respectively. The shortest path method using the Astar search algorithm with a screening algorithm is used to optimize the distribution of energy networks. The proposed methodology is verified by a hypothetical region from literature. The modified energy station and network planning methodology based on kernel density hotspots can reduce the total network length by 21.3%. Moreover, the proposed methodology can be applied easily and effectively to select the locations of the energy stations and determine the distribution of the energy networks in a regional integrated energy system.

Published

2020

14. Thermal Performance Analysis of an Absorption Cooling System Based on Parabolic Trough Solar Collectors

Author

Zhuang Wang, Rujing Yan, Guohua Shi, Jiangjiang Wang, and Xutao Zhang

Subjects

Thermal efficiency, Control and Optimization, Materials science, 020209 energy, Nuclear engineering, Cooling load, solar energy, Energy Engineering and Power Technology, 02 engineering and technology, lcsh:Technology, law.invention, Solar air conditioning, law, Thermal, solar cooling system, absorption chiller, parabolic trough solar collector (PTC), 0202 electrical engineering, electronic engineering, information engineering, Parabolic trough, Electrical and Electronic Engineering, Engineering (miscellaneous), Renewable Energy, Sustainability and the Environment, business.industry, lcsh:T, Coefficient of performance, Solar energy, Absorption refrigerator, Astrophysics::Earth and Planetary Astrophysics, business, Energy (miscellaneous)

Abstract

Solar radiation intensity significantly influences the cooling loads of building, and the two are correlated and accorded to a certain extent. This study proposes a double effect LiBr–H2O absorption cooling system based on the parabolic trough collector (PTC) of solar heat energy. Thermodynamic models including PTC and absorption chiller are constructed, and their accuracy is verified by comparing the simulation results and the experimental data. Subsequently, the impact of variable design parameters on the thermodynamic performance is analyzed and discussed. The analysis of a solar cooling system in a hotel case study is related to its operation in a typical day, the average coefficient of performance of the absorption chiller is approximately 1.195, and the whole solar cooling system achieves 61.98% solar energy utilization efficiency. Furthermore, the performance comparison of a solar cooling system in different types of building indicates that higher matching and a higher correlation coefficient between the transient solar direct normal irradiance and cooling load is helpful in decreasing the heat loss and improving systemic performance. The solar cooling system in the office building exhibits a correlation coefficient of approximately 0.81 and achieves 69.47% systemic thermal efficiency.

Published

2018