Your search keyword '"Electrical power output"' showing total 23 results

1. Prediction of Full-Load Electrical Power Output of Combined Cycle Power Plant Using a Super Learner Ensemble.

Author

Song, Yujeong, Park, Jisu, Suh, Myoung-Seok, and Kim, Chansoo

Subjects

MACHINE learning, BOOSTING algorithms, ELECTRIC power, STEAM-turbines, GAS turbines, COMBINED cycle power plants, POWER plants

Abstract

Combined Cycle Power Plants (CCPPs) generate electrical power through gas turbines and use the exhaust heat from those turbines to power steam turbines, resulting in 50% more power output compared to traditional simple cycle power plants. Predicting the full-load electrical power output ( P E ) of a CCPP is crucial for efficient operation and sustainable development. Previous studies have used machine learning models, such as the Bagging and Boosting models to predict P E . In this study, we propose employing Super Learner (SL), an ensemble machine learning algorithm, to enhance the accuracy and robustness of predictions. SL utilizes cross-validation to estimate the performance of diverse machine learning models and generates an optimal weighted average based on their respective predictions. It may provide information on the relative contributions of each base learner to the overall prediction skill. For constructing the SL, we consider six individual and ensemble machine learning models as base learners and assess their performances compared to the SL. The dataset used in this study was collected over six years from an operational CCPP. It contains one output variable and four input variables: ambient temperature, atmospheric pressure, relative humidity, and vacuum. The results show that the Boosting algorithms significantly influence the performance of the SL in comparison to the other base learners. The SL outperforms the six individual and ensemble machine learning models used as base learners. It indicates that the SL improves the generalization performance of predictions by combining the predictions of various machine learning models. [ABSTRACT FROM AUTHOR]

Published

2024

2. Real-Time Analysis for Enhancement of Photovoltaic Panel Efficiency and Quality.

Author

Zine, Bachir, Labiod, Chouaib, Srairi, Kamel, Benmouna, Amel, Becherif, Mohamed, Khechekhouche, Abderrahmane, Ravelo, Blaise, and Naoui, Mohamed

Subjects

PHOTOVOLTAIC cells, ELECTRIC power distribution grids, ALGORITHMS, OPEN-circuit voltage, REAL-time computing

Abstract

This study addressed the quality assessment of photovoltaic (PV) panels by analyzing their efficiency and electrical power under varying environmental conditions. A sophisticated algorithm was developed to extract and analyze PV panel voltage and current data in a complex manner, allowing the identification of key parameters such as open circuit voltage (Voc), short circuit current (Isc), and peak electrical power. These parameters were compared to the input power to accurately determine the panel efficiency. The novelty of this approach lies in its real-time implementation using a DC/DC (buck-boost) converter equipped with precise voltage and current sensors and running on a TMS320f379D board, linking theoretical knowledge with practical results. Experimental results demonstrated that temperature and irradiation significantly influence PV performance. With a 10°C increase in temperature, it resulted in a 5-10% decrease in output power, while a 100 W/m² increase in irradiation resulted in a 10-15% increase in output power. The study highlights the importance of considering both temperature and irradiation variations to optimize PV system design and operation, providing a robust method to assess PV panel quality in real-time. [ABSTRACT FROM AUTHOR]

Published

2024

3. Electrical Power Output Prediction of Combined Cycle Power Station

Author

CHEN Daijun, CHEN Lili, and LI Yangtao

Subjects

combined cycle power plant, electrical power output, feature extraction, kernel principle component analysis (kpca), forward selection, Applications of electric power, TK4001-4102, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Science

Abstract

In order to maximize the profit of a combined cycle power plant, it is important to accurately predict its full load power output. When a combined cycle power plant operates, the exhaust gas produced by the previous stage is used to drive the next stage heat engine to drive the generator, and its full-load electrical output is affected by ambient temperature, atmospheric pressure, relative humidity and exhaust pressure. Firstly, the kernel principle component analysis (KPCA) was used to perform feature combination dimensionality reduction for power generation related features to complete feature extraction. Then, the extreme gradient boosting algorithm (XGBoost) was used to score feature importance and the optimal feature subset was obtained by forward selection (FS). Finally, a KPCA-XGB-FS model was constructed for the prediction of hourly power output under full load of combined cycle power plants. By experimenting with real data from a combined power station and comparing with existing research methods using the same data, it is found that the method proposed in this paper can effectively predict the power output, and is better than the existing research methods.

Published

2024

4. Prediction of Full-Load Electrical Power Output of Combined Cycle Power Plant Using a Super Learner Ensemble

Author

Yujeong Song, Jisu Park, Myoung-Seok Suh, and Chansoo Kim

Subjects

Combined Cycle Power Plants, electrical power output, machine learning, Super Learner, cross-validation, ensemble, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Combined Cycle Power Plants (CCPPs) generate electrical power through gas turbines and use the exhaust heat from those turbines to power steam turbines, resulting in 50% more power output compared to traditional simple cycle power plants. Predicting the full-load electrical power output (PE) of a CCPP is crucial for efficient operation and sustainable development. Previous studies have used machine learning models, such as the Bagging and Boosting models to predict PE. In this study, we propose employing Super Learner (SL), an ensemble machine learning algorithm, to enhance the accuracy and robustness of predictions. SL utilizes cross-validation to estimate the performance of diverse machine learning models and generates an optimal weighted average based on their respective predictions. It may provide information on the relative contributions of each base learner to the overall prediction skill. For constructing the SL, we consider six individual and ensemble machine learning models as base learners and assess their performances compared to the SL. The dataset used in this study was collected over six years from an operational CCPP. It contains one output variable and four input variables: ambient temperature, atmospheric pressure, relative humidity, and vacuum. The results show that the Boosting algorithms significantly influence the performance of the SL in comparison to the other base learners. The SL outperforms the six individual and ensemble machine learning models used as base learners. It indicates that the SL improves the generalization performance of predictions by combining the predictions of various machine learning models.

Published

2024

5. 联合循环发电站电力输出预测.

Author

陈代俊, 陈里里, and 李阳涛

Abstract

Copyright of Power Generation Technology is the property of Power Generation Technology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

6. Tri-generation System Integration and Evaluation

Author

Elmer, Theo and Elmer, Theo

Published

2017

7. Smart Electronics and Sensors

Author

Abdullaeva, Zhypargul and Abdullaeva, Zhypargul

Published

2017

8. Performance of a Thermoelectric Module Based on n-Type (La0.12Sr0.88)0.95TiO3−δ and p-Type Ca3Co4−xO9+δ.

Author

Kanas, Nikola, Skomedal, Gunstein, Desissa, Temesgen Debelo, Feldhoff, Armin, Grande, Tor, Wiik, Kjell, and Einarsrud, Mari-Ann

Subjects

WEATHER, X-ray diffraction, ATMOSPHERE, STRONTIUM, PERFORMANCES

Abstract

Here, we present the performance of a thermoelectric (TE) module consisting of n-type (La0.12Sr0.88)0.95TiO3 and p-type Ca3Co4−xO9+δ materials. The main challenge in this investigation was operating the TE module in different atmospheric conditions, since n-type has optimum TE performance at reducing conditions, while p-type has optimum at oxidizing conditions. The TE module was exposed to two different atmospheres and demonstrated higher stability in N2 atmosphere than in air. The maximum electrical power output decreased after 40 h when the hot side was exposed to N2 at 600°C, while only 1 h at 400°C in ambient air was enough to oxidize (La0.12Sr0.88)0.95TiO3 followed by a reduced electrical power output. The module generated maximum electrical power of 0.9 mW (∼ 4.7 mW/cm2) at 600°C hot side and δT ∼ 570 K in N2, and 0.15 mW (∼ 0.8 mW/cm2) at 400°C hot side and δT ∼ 370 K in air. A stability limit of Ca3Co3.93O9+δ at ∼ 700°C in N2 was determined by in situ high-temperature x-ray diffraction. [ABSTRACT FROM AUTHOR]

Published

2020

9. Influence of cooling water flow rate and temperature on the photovoltaic panel power

Author

Belyamin, Belyamin, Fulazzaky, Mohamad Ali, Roestamy, Martin, and Subarkah, Rahmat

Published

2022

10. Global Energy Situation

Author

Bauer, Gottfried H., Englert, Berthold-Georg, Series editor, Hänggi, Peter, Series editor, Jones, Richard A L, Series editor, von Löhneysen, H., Series editor, Raimond, Jean-Michel, Series editor, Theisen, Stefan, Series editor, Vollhardt, Dieter, Series editor, Rubio, Angel, Series editor, Hjorth-Jensen, Morten, Series editor, Wells, James D., Series editor, Lewenstein, Maciej, Series editor, Zank, Gary P, Series editor, and Bauer, Gottfried H.

Published

2015

11. Impact of grid‐tied large‐scale photovoltaic system on dynamic voltage stability of electric power grids.

Author

Refaat, Shady S., Abu‐Rub, Haitham, Sanfilippo, Antonio P., and Mohamed, Amira

Abstract

Perfect power system voltage stability is not possible in practice. Generally, the power grid is continually exposed to changes in its load and operating conditions. Therefore, dynamic stability analysis is one the most important and effective elements for greater security, stability and reliability of planning, design, operation and economic aspects of electric power networks. This study investigates and reports on the dynamic stability of the power system with a large‐scale photovoltaic system (L‐S PV). Two different scenarios with centralised PV power plants are considered in the medium voltage level without voltage regulation capabilities. Simulation results with these scenarios will show how the voltage instability decreases with the L‐S PV based on the bus status, disturbance location, and disturbance duration. In addition, the study discusses network terminal voltage, generator's rotor angle, generator's terminal current, generator's reactive power and electrical power output. This study is an extension of the earlier published conference paper. [ABSTRACT FROM AUTHOR]

Published

2018

12. Experimental investigation of the effect of partial shading on photovoltaic performance.

Author

Mamun, Mohammad Abdullah Al, Hasanuzzaman, Md, and Selvaraj, Jeyraj

Abstract

Partial shading of a photovoltaic (PV) installation has an inconsistent impact on power production. This study investigates the effect of partial shading on PV performance. The experiments were carried out with a 90‐W PV module under both variable and constant irradiations with shaded area increased from 0 to 80% to observe the effect of variable solar radiation at certain shading points. The effect of shading under irradiation levels from 300 to 800 W/m2 was investigated. At a 600 W/m2 irradiation level, the shading impact factor was 1.25 with a 25% shading, while at 75% shading the impact factor decreased to 0.86. Results also show that for every 100 W/m2 increase in irradiation level, the electrical power output was enhanced by 3.89, 3.37, 2.27, and 2.02 W at 0, 25, 50, and 75% shading, respectively. The efficiency level was increased by 0.29, 0.27, 0.25, and 0.22% at 0, 25, 50, and 75% shading, respectively. Increasing the shaded area by 10% causes a 12.41 W drop in power output and a 2.3% drop in electrical efficiency. Partial shading not only deteriorates the PV performance, but also causes long‐term degradation of the module. [ABSTRACT FROM AUTHOR]

Published

2017

13. Wave energy resource assessment along the Southeast coast of Australia on the basis of a 31-year hindcast.

Author

Morim, Joao, Cartwright, Nick, Etemad-Shahidi, Amir, Strauss, Darrell, and Hemer, Mark

Subjects

*WAVE energy, *COASTS, *CLIMATE change forecasts, *POWER resources, *BOUNDARY value problems

Abstract

In this study, a long-term assessment of the wave energy resource potential for the Australian southeast shelf is performed from deep to shallow water, based on a 31-year wave hindcast. The hindcast, covering the period from 1979 to 2010, has been performed at high spatio-temporal resolution with the wave energy transformation model SWAN using calibrated source-term parameters. The model has been applied with a variable spatial resolution of up to approximately 500 m and at 1 h temporal resolution and driven with high-resolution, non-stationary CFSR wind fields and full 2D spectral boundary conditions from WaveWatch III model. Model validation was conducted against wave measurements from multiple buoy sites covering 10–31 years and showed a relatively high correlation between hindcast and measured significant wave height ( H s ) and mean wave direction ( θ m ). Maps of wave power resource distribution for annual and seasonal mean potential were generated along with the maps of resource reliability and variability. The high resolution allowed us to perform in-depth analysis of wave power characteristics, providing resource knowledge on seasonal and longer-term variability necessary for reliable and optimal design of wave technology. The most promising area for wave power exploitation was found to be the central coast of New South Wales, where various high-energy hotspots were selected for a further analysis. For each of the considered hotspots, the wave power magnitude, variability and consistency were carefully assessed and characterized by means of sea state parameters and mean wave directions. Finally, estimates of electric power outputs from different types of pre-commercial wave energy converter devices were drawn for each hotspot based on the wave data hindcast and discussed. [ABSTRACT FROM AUTHOR]

Published

2016

14. An Overview of Cellulose-Based Nanogenerators

Author

Annamalai, P. K., Nanjundan, A. K., Dubal, D. P., Baek, J. -B, Annamalai, P. K., Nanjundan, A. K., Dubal, D. P., and Baek, J. -B

Abstract

Developing nanogenerators (NGs) is achieved by exploiting the piezoelectric, triboelectric, and pyroelectric effects of both organic and inorganic materials. Many exhibit beneficial electrical properties (dielectric, conductive, or insulating) or have surfaces that are polarizable upon friction or physical contact. Recently, biomass-derived materials and recycled materials, whose electrical activity can be induced, are explored for application in the design of more sustainable, cost-effective, biodegradable, disposable NGs, and have demonstrated a wide range of output (microenergy) power densities. Among them, cellulose, the most abundant biopolymer, is found to offer excellent opportunities for designing and manufacturing NGs with multifunctional capacities. Cellulose can be derived into varied forms with multifunctionalities and physical morphologies. This account provides an overview of how cellulose is utilized in creating NGs based on piezoelectric, triboelectric, and pyroelectric effects. Because the mechanical properties of cellulose are tunable, current research trends on NGs originate with the triboelectric effect. The discussion here focuses on design, fabrication methods, achievable electrical power output, and combinations with other materials and devices. Challenges in efficient fabrication and consistent power densities, and opportunities for integrating different technologies and developing more sustainable (in terms of economic, environmental, and ecological) nature–human–machine interfacial devices are also discussed. © 2021 Wiley-VCH GmbH

Published

2021

15. Effect of resistive load on the performance of an organic Rankine cycle with a scroll expander.

Author

Zhu, Jie, Chen, Ziwei, Huang, Hulin, and Yan, Yuying

Subjects

*RESISTIVE force, *RANKINE cycle, *ELECTRICAL resistivity, *ISENTROPIC processes, *ISOTHERMAL efficiency

Abstract

An experimental investigation is performed for an organic Rankine cycle system with different electrical resistive loads. The test rig is set up with a small scroll expander-generator unit, a boiler and a magnetically coupled pump. R134a is used as the working fluid in the system. The experimental results reveal that the resistive load coupled to the scroll expander-generator unit affects the expander performance and power output characteristics. It is found that an optimum pressure ratio exists for the maximum power output. The optimal pressure ratio of the expander decreases markedly as the resistive load gets higher. The optimum pressure ratio of the scroll expander is 3.6 at a rotation speed of 3450 r/min for a resistive load of 18.6 Ω. The maximum electrical power output is 564.5 W and corresponding isentropic and volumetric efficiencies are 78% and 83% respectively. [ABSTRACT FROM AUTHOR]

Published

2016

16. Numerical heat transfer modeling and climate adaptation analysis of vacuum-photovoltaic glazing.

Author

Tan, Yutong, Peng, Jinqing, Luo, Yimo, Luo, Zhengyi, Curcija, Charlie, and Fang, Yueping

Subjects

*HEAT transfer, *ATMOSPHERIC models, *GLAZES, *THERMAL insulation, *HEAT losses

Abstract

• Numerical model for a four-layer CdTe-based VPV glazing was developed. • The model was validated experimentally with a U-value of 0.92 W/(m2⋅K). • About 60% heat loss and heat gain can be reduced by VPV in cold and hot climates. • More than 40 kWh/m2 average power generation of VPV windows can be achieved. Vacuum-photovoltaic (VPV) glazing has attracted much attention due to its excellent thermal insulation performance and its ability to utilize solar energy. However, few simulation models have been established based on actual products and rarely have been validated by experiments. In this paper, a four-layer CdTe-based VPV glazing was developed and the corresponding numerical heat transfer model was established with the integration of a dynamic power generation model. The numerical model was then validated against both the results from the WINDOW program and a guarded hot box experiment. Afterward, the validated model was employed to analyze the energy and power generation performance of the VPV glazing in diverse climate zones in China with Harbin, Beijing, Changsha, Guangzhou, and Kunming used as representative cities. The numerical simulation results indicate that the U-value of the proposed VPV glazing is 0.89 W/(m2⋅K), which is in good agreement with the experimental results. Compared with a normal double glazing, the average energy reductions achieved with VPV glazing in air conditioning seasons are 128 kWh/m2, 23 kWh/m2, 45 kWh/m2, and 52 kWh/m2 in Harbin, Beijing, Changsha, and Guangzhou, respectively. In addition, the average annual power outputs of VPV glazing in Harbin, Beijing, Changsha, Guangzhou, and Kunming are 47 kWh/m2, 48 kWh/m2, 34 kWh/m2, 36 kWh/m2, and 45 kWh/m2, respectively. The numerical model developed in this study can be used for energy-saving potential analysis and optimization of VPV glazing in different meteorological conditions, the results of which could provide guidance for the effective application of VPV glazing. [ABSTRACT FROM AUTHOR]

Published

2022

17. Thermoeconomic Analysis And Assessment Of Gaziantep Municipal Solid Waste Power Plant

Author

Aysegul Abusoglu, Emrah Özahi, Alperen Tozlu, and Bayburt University

Subjects

Municipal solid waste, Thermoeconomic analysis, Mobile incinerator, Power station, 020209 energy, General Physics and Astronomy, Waste collection, 02 engineering and technology, Exergy efficiencies, Auxiliary equations, Energy and exergy, Cost benefit analysis, Specific exergy, 0202 electrical engineering, electronic engineering, information engineering, Exergy, Refuse-derived fuel, Electrical power output, Waste management, Solid wastes, Thermal hydrolysis, 021001 nanoscience & nanotechnology, Costs, Step by step procedure, Waste-to-energy, Waste treatment, Environmental science, 0210 nano-technology, Power plant system

Abstract

This paper presents a thermoeconomic analysis and assessment of a municipal solid waste power plant system in Gaziantep. The operation of an existing municipal solid waste power plant is described in detail and a thermoeconomical methodology based on exergoeconomic relations and specific exergy costing (SPECO) method is provided to allocate cost flows through subcomponents of the plant. SPECO method is based on a step by step procedure which begins from identification of energy and exergy values of all states defined in the present system through fuel (F) and product (P) approach and ends at the point of establishing related exergy based cost balance equations together with auxiliary equations. The actual exergy efficiency of the solid waste power plant is determined to be 47.84% which shows that 52.16% of the total exergy input to the plant is destroyed. The net electrical power output of the Gaziantep municipal solid waste power plant is 5.655 MW. The total cost rate of the power plant is evaluated as 18.44$/h as a result of thermoeconomic analyses.

Published

2017

18. Experimental characterisation of a micro Humid Air Turbine: assessment of the thermodynamic performance

Author

UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, Montero Carrero, M., De Paepe, W., Magnusson, J., Parente, A., Bram, S., Contino, Francesco, UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, Montero Carrero, M., De Paepe, W., Magnusson, J., Parente, A., Bram, S., and Contino, Francesco

Abstract

Despite appearing as a promising technology for distributed generation, micro Gas Turbines (mGTs) have not yet managed to penetrate the small-scale Combined Heat and Power (CHP) market. The energy efficiency of mGTs amounts to 80% whenever both heat and electricity are required. However, when the heat demand is low, the hot exhaust gases have to be directly blown off and the electrical efficiency of the unit (∼30%) is not high enough to sustain profitable operation. Water injection, achieved when transforming the mGT into a micro Humid Air Turbine (mHAT), allows making use of the exhaust gas heat in such cases, thus increasing electrical efficiency of the technology and improving its feasibility. Although the enhanced performance of the mHAT cycle has been thoroughly investigated from a numerical point of view, results regarding the experimental behaviour of this technology remain scarce. In this paper, we present the experimental characterisation of the mHAT located at Vrije Universiteit Brussel (VUB) which is based on the T100 mGT equipped with a spray saturation tower. These are the first experimental results of such an engine working at nominal load with water injection. In addition, the control system of the unit has been modified so that it can operate either at constant electrical power output (the default setting) or at constant rotational speed. The latter option allowed better assessing the effect of water injection. Experimental results demonstrate the patent benefits of water injection on mGT performance: at fixed rotational speed, the power output of the mHAT increases by more than 30% while fuel consumption rises only by 11%. Overall, the electrical efficiency in wet operation increases by up to 4.2% absolute points. © 2017 Elsevier Ltd

Published

2017

19. Waste heat recovery optimization in micro gas turbine applications using advanced humidified gas turbine cycle concepts

Author

UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, De Paepe, W., Montero Carrero, M., Bram, S., Contino, Francesco, Parente, A., UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, De Paepe, W., Montero Carrero, M., Bram, S., Contino, Francesco, and Parente, A.

Abstract

Introduction of water in a micro Gas Turbine (mGT) has proven to be a very effective method to recover waste heat into the cycle, since it increases the mGT electrical efficiency significantly. Different routes exist for water introduction in the mGT cycle. Classical routes, like injection of steam/preheated water or the micro Humid Air Turbine (mHAT) concept, where water is introduced in the cycle by means of a saturation tower, have shown to have high potential. However none of the previously mentioned cycles exploits the full thermodynamic potential for waste heat recovery through water introduction. More advanced humidified Gas Turbine (GT) cycles have been proposed and studied for large scale GTs. So far, none of these concepts have been applied on mGT scale, despite their high potential. In this paper, we study the impact of these different, more advanced, humidified GT cycle concepts on the mGT performance. The different selected cycles – next to the classical steam injection or injection of (preheated) liquid water in the recuperated cycle and the mHAT – were: micro Humid Air Turbine Plus (mHAT+), Advanced Humid Air Turbine (AHAT) and the REgenerative EVAPoration (REVAP®) cycle concept. The impact of these concepts on the mGT cycle performance has been studied on the Turbec T100 mGT. Simulations indicated that humidifying the air of the mGT has a significant beneficial effect on cycle performance due to the increased waste heat recovery, resulting in a higher electrical power output (at constant rotational speed) or reduced fuel consumption (at constant power output), both leading to an increased electrical efficiency. Depending on the different cycle layout used, more or less waste heat could be recovered from the exhaust gas. The REVAP® concept with feedwater preheat was identified as the optimal cycle layout within the selected options. By applying this concept to the Turbec T100, most waste heat could be recovered, achieving the highest electrical effici

Published

2017

20. Effect of resistive load on the performance of an organic Rankine cycle with a scroll expander

Author

Jie Zhu, Yuying Yan, Hulin Huang, and Ziwei Chen

Subjects

Overall pressure ratio, Materials science, Maximum power principle, 020209 energy, Scroll, 02 engineering and technology, Organic Rankine cycle, 7. Clean energy, Industrial and Manufacturing Engineering, Control theory, 0202 electrical engineering, electronic engineering, information engineering, Scroll expander, Electrical and Electronic Engineering, Electrical power output, Civil and Structural Engineering, Resistive touchscreen, Isentropic process, Mechanical Engineering, Optimal pressure ratio, Rotational speed, Building and Construction, Mechanics, Pollution, General Energy, Resistive load, Working fluid

Abstract

An experimental investigation is performed for an organic Rankine cycle system with different electrical resistive loads. The test rig is set up with a small scroll expander-generator unit, a boiler and a magnetically coupled pump. R134a is used as the working fluid in the system. The experimental results reveal that the resistive load coupled to the scroll expander-generator unit affects the expander performance and power output characteristics. It is found that an optimum pressure ratio exists for the maximum power output. The optimal pressure ratio of the expander decreases markedly as the resistive load gets higher. The optimum pressure ratio of the scroll expander is 3.6 at a rotation speed of 3450 r/min for a resistive load of 18.6 ?. The maximum electrical power output is 564.5 W and corresponding isentropic and volumetric efficiencies are 78% and 83% respectively.

Published

2016

21. Experimental characterisation of a humidified t100 micro gas turbine

Author

UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, Carrero, M.M., De Paepe, W., Magnusson, J., Parente, A., Bram, S., Contino, Francesco, ASME Turbo Expo 2016: Turbomachinery Technical Conference and Exposition, GT 2016, UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, Carrero, M.M., De Paepe, W., Magnusson, J., Parente, A., Bram, S., Contino, Francesco, and ASME Turbo Expo 2016: Turbomachinery Technical Conference and Exposition, GT 2016

Abstract

Despite the potential of micro Gas Turbines (mGTs) for Combined Heat and Power (CHP), this technology still poses limitations that curb its widespread adoption, especially for applications with a variable heat demand. In fact, whenever the user heat demand is low, mGTs are generally shut down. Otherwise, the high temperature exhaust gases have to be blown off and the resulting electrical efficiency is not high enough to sustain a profitable operation. If, instead of released, the heat in the exhaust gases is re-inserted in the cycle by injecting hot water and transforming the mGT into a micro Humid Air Turbine (mHAT) the electrical efficiency can be increased during periods of reduced heat demand, thus improving the economics of the technology. Although the enhanced performance of the mHAT cycle has been thoroughly investigated from a numerical point of view, results regarding the experimental behaviour of this technology remain scarce. In this paper, we present the experimental characterisation of the mHAT located at the Vrije Universiteit Brussel (VUB): based on the T100 mGT and equipped with a spray saturation tower. These are the first experimental results of such an engine working at nominal load with water injection. In addi tion, the control system of the unit has been modified so that it can operate either at constant electrical power output (the default setting) or at constant rotational speed. The latter option allowed to better assess the effect of water injection. Eperimental results demonstrate the patent benefits of water injection on mGT performance: At fixed rotational speed, the power output of the mHAT increases by more than 30%while the fuel consumption rises only by 11%. Overall, the electrical efficiency in wet operation increases by up to 4:2% absolute points. Future work will involve further optimising the current facility to reduce pressure losses in the air and water circuits. In addition, we will carry out transient simulations and experime

Published

2016

22. Effect of the fuel type on the performance of an externally fired micro gas turbine cycle

Author

Baina, Fabiola, Malmquist, Anders, Alejo, Lucio, Fransson, Torsten H., Baina, Fabiola, Malmquist, Anders, Alejo, Lucio, and Fransson, Torsten H.

Abstract

Externally fired gas turbines open the possibility of using fuels of lower quality than conventional gas turbines and internal combustion engines. This is because in externally fired gas turbines, the flue gases heat the compressed air in a high temperature heat exchanger. This heat exchanger can more easily deal with contaminants present in the flue gases. In this regard, the configuration of externally fired gas turbines represents an interesting option for biomass gasification gas. The contaminants and low heating value (LHV) of this fuel have made it difficult to find a conversion technology for heat and power generation. For this reason, it is important to study the influence of biomass derived gas as fuel on the performance of this system and consider the effects of the contaminants in the high temperature heat exchanger. This is studied in this work through simulations using Aspen Plus and Matlab. The test data of an externally fired micro gas turbine prototype was used to validate the simulation. The fuel considered was biomass gasification gas with varying concentrations of benzene 100, 10 and 1 g/Nm3 (hereafter named m100, m10, and m1 respectively). Additionally, mixtures of biomass derived gas and methane were studied for 10 and 50% of the thermal power of the combustor. The fuel inlet temperature to the combustor varied from 150 °C to 750 °C in order to represent the fuel gas after removal of particles by a cyclone and a filter. The results showed that the electrical power output increases when high fuel inlet temperatures to the combustor are used. Additionally, although it would be expected that fuels with higher LHV (lower heating value) show higher temperatures and higher output power, this does not always occur because of the composition of the fuels and their respective flue gas temperatures. The addition of methane does not have a large effect on the electrical power output. For a fixed temperature limit in the heat exchanger, the composition of t, QC 20150629. Updated from manuscript to article in journal.

Published

2015

23. Numerical Modeling of c-Si PV Modules by Coupling the Semiconductor with the Thermal Conduction, Convection and Radiation Equations

Author

Vogt, Malte R., Holst, Hendrik, Winter, Matthias, Brendel, Rolf, Altermatt, Pietro P., Vogt, Malte R., Holst, Hendrik, Winter, Matthias, Brendel, Rolf, and Altermatt, Pietro P.

Abstract

Commonly, the thermal behavior of solar cell modules is calculated with analytical approaches using non wavelength-dependent optical data. Here, we employ ray tracing of entire solar modules at wavelengths of 300-2500 nm to calculate heat sources. Subsequently, finite element method (FEM) simulations are used to solve the semiconductor equations coupled with the thermal conduction, thermal convection, and thermal radiation equations. The implemented model is validated with measurements from an outdoor test over the period of an entire year. Our ray tracing analysis of different solar modules under the AM.15G spectrum shows that, for a standard module about 18.9% of the sun's intensity becomes parasitically absorbed. A loss analysis shows that the biggest parasitic heat source is the cell's full-area rear side metallization. We hence propose the use of a SiNx layer as rear side mirror to reduce the parasitic absorption to 11.7%. This change can lead to a 3.2 °C lower module operating temperature, which results in an about 5 W higher electrical power output when considering a typical 260 W module.

Published

2015