Your search keyword '"Aryanfar, Yashar"' showing total 6 results

1. ENERGY, EXERGY, AND EXERGOECONOMIC ANALYSIS OF A TRANS-CRITICAL CO2 CYCLE POWERED BY A SINGLE FLASH GEOTHERMAL CYCLE IN WITH/WITHOUT ECONOMIZER WORKING MODES.

Author

ARYANFAR, Yashar, MOHTARAM, Soheil, GARCIA CASTELLANOS, Humberto, TAG-ELDIN, Elsayed M., ARSLAN, Busra, DEIFALLA, Ahmed, RAGAB, Adham E., and HongGuang SUN

Subjects

*EXERGY, *GROUND source heat pump systems, *FIRST law of thermodynamics, *SECOND law of thermodynamics, *GEOTHERMAL resources, *COST analysis, *INDUSTRIAL costs

Abstract

The global utilization of RES, particularly geothermal energy, is rising and the inefficient nature of geothermal cycles necessitates recovering lost heat. This research proposes a combined power generation cycle that simulates integrating a trans-critical CO2 cycle with a single flash geothermal cycle, utilizing the engineering equation solver. The study contrasts the system's performance between two operating states: "Without Economizer" and "With Economizer". The investigation analyzes the impact of an economizer on key output parameters, including energy efficiency, exergy efficiency, and net power output. In the "With Economizer" operating state, the net power output experiences a noticeable increase from 201.5 kW to 204.7 kW, resulting in a 1.58% enhancement in the performance of the "With Economizer" system. The energy efficiency metric demonstrates a corresponding improvement, rising by 1.55% from 3.28% in the "Without Economizer" system to 3.331% in the "With Economizer" system, aligning with the principles of the First law of thermodynamics. Furthermore, the energy efficiency, expressed as a percentage of energy units, shows an increase from 16.3% in the "Without Economizer" system to 16.56% in the "With Economizer" system, representing a 1.595% improvement based on the Second law of thermodynamics or exergy. Regarding cost analysis, the study identifies the optimal separator pressure value for the system without an economizer, equivalent to 23. This configuration achieves a total cost rate of 01 $ per GJ. Conversely, in the system with an economizer, the optimal pressure value for the production cost rate is 322.4 kPa, resulting in a cost rate of 23.57 $ per GJ. [ABSTRACT FROM AUTHOR]

Published

2024

2. A COMPETITIVE STUDY OF A GEOTHERMAL HEAT PUMP EQUIPPED WITH AN INTERMEDIATE ECONOMIZER FOR R134a AND R513a WORKING FLUIDS.

Author

ARYANFAR, Yashar, MOHTARAM, Soheil, GHAZY, Ahmed, KAANICHE, Khaled, GARCIA-ALCARAZ, Jorge Luis, and HongGuang SUN

Subjects

*HEAT pumps, *GROUND source heat pump systems, *SOIL temperature, *HEAT pipes, *AIR conditioning

Abstract

At temperatures below 60 °C, the best way to use geothermal sources for heating is to use heat pumps. A heat pump can provide air conditioning for a residential, commercial, etc., all year round by heating in winter and cooling in summer using a low temperature source. Also, a heat pump can be used for water distillation through evaporation. The ground source heat pump with a high COP and low temperature thermal energy sources is one of the best technologies for using RES. In the present study, the effects of changing ambient temperature and soil temperature on a heat pump's overall COP and energy efficiency are investigated using a simulated geothermal heat pump with an economizer. The system's thermodynamic simulation is first performed in the engineering equation solver software for R134a and R513a working fluids. The exergy destruction of different components for both working fluids was calculated and displayed as a figure. The COP of the heat pump for R134a working fluid is equal to 3.916, equal to 3.729 for R513a working fluid, which indicates that R134a fluid has about 5% better performance. The COP of the system for R134a working fluid is equal to 3.662, which is equal to 3.504 for R513a working fluid, which indicates that R134a fluid has about 4.5% better performance. [ABSTRACT FROM AUTHOR]

Published

2023

3. Exergy and exergoenvironmental assessment of a geothermal heat pump and a wind power turbine hybrid system in Shanghai, China.

Author

Aryanfar, Yashar and Alcaraz, Jorge Luis García

Subjects

HEAT pumps, GROUND source heat pump systems, HYBRID power systems, WIND power, WIND turbines, EXERGY, HYBRID systems

Abstract

Geothermal heat pumps are one of the most growing and cost-effective renewable energy technologies based on the temperature difference between the ground and the environment. In the cold seasons, the temperature inside the soil or water is higher than the ambient temperature. Therefore, the heat pump is used to extract the warm temperature of the ground into the house or any other controlled space. In the summer, the air temperature is higher than the temperature of the soil or water. This temperature difference is used again to cool the house or any other environment. This paper examines the energy and exergy assessments of a hybrid system in Shanghai, China, that employs a geothermal heat pump with an economizer for winter heating and a wind turbine to provide clean electricity. The complete set of procedures, as well as every component and every aspect of the hybrid system, have all been carefully examined. The heat pump's coefficient of performance is 3.916, its net power output is 22.03 kW, its overall energy efficiency is 77.2%, and its exergy efficiency is 25.49%. [ABSTRACT FROM AUTHOR]

Published

2023

4. Exergy analyses and optimization of a single flash geothermal power plant combined with a trans-critical CO2 cycle using genetic algorithm and Nelder–Mead simplex method.

Author

Huang, Jian, Abed, Azher M., Eldin, Sayed M., Aryanfar, Yashar, and García Alcaraz, Jorge Luis

Subjects

GEOTHERMAL power plants, SIMPLEX algorithm, GENETIC algorithms, GROUND source heat pump systems, EXERGY, GEOTHERMAL resources

Abstract

Compared with conventional fossil fuel sources, geothermal energy has several advantages. The produced geothermal energy is safe for the environment and suitable for meeting heating power needs. Because the hot water used in the geothermal process can be recycled and used to generate more steam, this energy is sustainable. Furthermore, the climate change does not affect geothermal power installations. This study suggests a combined power generation cycle replicating using the EES software that combines a single flash cycle with a trans-critical carbon dioxide cycle. The findings demonstrate that, in comparison to the BASIC single flash cycle, the design characteristics of the proposed system are greatly improved. The proposed strategy is then improved using the Nelder–Mead simplex method and Genetic Algorithm. The target parameter is exergy efficiency, and the three assumed variable parameters are separator pressure, steam turbine outlet pressure, and carbon dioxide turbine inlet pressure. The system's exergy efficiency was 32.46% in the default operating mode, rising to 39.21% with the Genetic Algorithm and 36.16% with the Nelder–Mead simplex method. In the final step, the exergy destruction of different system components is calculated and analyzed. Highlights: Designing and simulating a combined single flash geothermal cycle with a trans-critical carbon dioxide cycle in the EES software. Genetic algorithms (GA) and the Nelder–Mead simplex (NMS) method are used to optimize the proposed system to increase the system's exergy efficiency. Examining the system's various components' energy destruction rates. [ABSTRACT FROM AUTHOR]

Published

2023

5. Thermodynamic investigation of a single flash geothermal power plant powered by carbon dioxide transcritical recovery cycle.

Author

Wang, Hao, Yan, Gongxing, Tag-Eldin, Elsayed, Chaturvedi, Rishabh, Aryanfar, Yashar, Luis García Alcaraz, Jorge, Talal Amin, Majdi, and Moria, Hazim

Subjects

GEOTHERMAL power plants, CARBON dioxide, HEAT recovery, GEOTHERMAL resources, GROUND source heat pump systems, ENERGY consumption, ALTERNATIVE fuels

Abstract

[Display omitted] • A new arrangement of a single flash geothermal power plant with a transcritical carbon dioxide recovery cycle is presented. • Energy analysis and exergy have been performed for both BASIC and recovery performance modes. • The results show that the proposed system in the recovery mode with a net power of 401.40 kW, energy efficiency of 53.6%, and exergy efficiency of 46.32% has been calculated. • Compared to the basic operating mode, the total output values of energy, energy efficiency and exergy efficiency show an increase of 149.9 kW, 2.39% and 12.12%, respectively. The use of new energy sources, such as geothermal energy, is rapidly expanding worldwide, and it is a viable alternative to fossil fuels. This paper proposes a geothermal power generation system (combined single flash geothermal cycle with transcritical carbon dioxide recovery cycle). To improve system performance, a recuperator is used to recover some of the heat loss. The proposed system simulation is performed in EES software and then validated by previous research. The proposed system is analyzed from the perspective of energy and exergy. The effects of the proposed system separator pressure, carbon dioxide turbine inlet pressure and carbon dioxide condenser outlet temperature on energy efficiency, exergy efficiency and system net power output have been investigated. Findings show that the proposed system in recovery mode has a net power output of 401.40 kW, energy efficiency of 53.6 percent, and exergy efficiency of 46.32 percent, which are significantly higher than the basic mode's values of 149.9 kW, 2.39 percent, and 12.12 percent, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

6. Conventional and advanced exergy analysis of a single flash geothermal cycle.

Author

Tang, Xianzhi, Yan, Gongxing, Abed, Azher M., Sharma, Aman, Tag-Eldin, Elsayed, Aryanfar, Yashar, and Alcaraz, Jorge Luis García

Subjects

EXERGY, THERMODYNAMIC cycles, ENERGY conversion, GROUND source heat pump systems, SYSTEMS design, ENGINEERING systems, SYSTEMS engineering

Abstract

In this paper, the inefficiency of the studied energy conversion system is identified to reduce losses and improve performance. A conventional exergy analysis has limitations that it is not able to detect and this detection is done with advanced exergy analysis. The main role of advanced exergy analysis is to help engineers improve system design and performance by providing information. This provision of information is done by isolating the exergy destruction. Separation of exergy destruction into endogenous/exogenous and unavoidable/avoidable components presents a new development in the exergy analysis of energy conversion systems, which in this paper combines both concepts. This separation increases the accuracy of the exergy analysis and facilitates the improvement of a system. The method used in this paper for separation is the thermodynamic cycle method, which is based on determining the temperature levels for ideal and irreversible cycles. Highlights: The single flash geothermal cycle was subjected to advanced exergy analysis. Endogenous/exogenous and unavoidable/avoidable energy destruction were investigated. The results of the enhanced exergy analysis are distinct and more practical. [ABSTRACT FROM AUTHOR]

Published

2022