Conventional Energy Sources Research Articles

Research on the matching relationship of multi-energy collaborative temperature control in factory farming system based on TRNSYS

In light of the escalating energy crisis and the imperative to address climate change, there exists a pervasive global consensus advocating the reduction of carbon emissions and the exploration of novel energy sources. Despite this consensus, the realm of factory farming continues to rely upon conventional energy sources for heating purposes. This study focuses on the investigation into the multi-energy heating system employed by an aquaculture company in Dalian City. We undertook the optimization of critical parameters within this system and formulate a comprehensive model for the multi-energy system using the TRNSYS transient simulation platform. The optimization process employs the Hooke-Jeeves algorithm, implemented through GenOpt software, with the system annual value cost serving as the objective function. Optimization variables include solar collector area, solar collector slope, thermal storage tank volume, seawater source heat pump power, and wastewater plate heat exchanger area. The findings of this investigation reveal a marked enhancement in the Coefficient of Performance (COP) and overall system performance after optimization. The resultant annual operating cost was $3133.61, indicating a substantial reduction of $1151.86 compared to the pre-optimization period’s cost. The static payback period is determined to be 9.43 years. During the heating period, in contrast to traditional boiler heating, the optimized system manifests a reduction in coal consumption of 4485.03 kg, accompanied by a cumulative decrease in pollutant emissions totaling 11544.46 kg. This substantiates the system’s cumulative economic and environmental viability.

Visible Light-Driven Hydrogen Evolution Catalysis by Heteroleptic Ni(II) Complexes with Chelating Nitrogen Ligands: Probing Ligand Substituent Position and Photosensitizer Effects

This study aims to advance the field of green chemistry and catalysis by exploring alternatives to conventional non-renewable energy sources. Emphasis is placed on hydrogen as a potential fuel, with a focus on the catalytic properties of Ni(II) complexes when coordinated with o-phenylenediamine and diimine ligands. We report the synthesis and comprehensive characterization, with various physical and spectroscopic techniques, of three heteroleptic Ni(II) complexes: [Ni(1,10-phenanthroline)(o-phenylene diamine)] (1), [Ni(2,2-dimethyl-2,2-bipyridine)(o-phenylene diamine)] (2), and [Ni(5,5-dimethyl-2,2-bipyridine)(o-phenylene diamine)] (3). The catalytic activity of these complexes for hydrogen evolution was assessed through photochemical studies utilizing visible light irradiation. Two distinct photosensitizers, fluorescein and quantum dots, were examined under diverse conditions. Additionally, their electrocatalytic behavior was investigated to elucidate the hydrogen evolution reaction (HER) mechanism, revealing a combined proton-coupled electron transfer (PCET)/electron-coupled proton transfer (ECPT) mechanism attributed to the chemical nature of the diamine ligand. The influence of ligand substituent position, ligand chemical nature, and photosensitizer type on catalytic performance was systematically studied. Among the complexes investigated, complex 2 demonstrated superior catalytic performance, achieving a turnover number (TON) of 3357 in photochemical experiments using fluorescein as a photosensitizer. Conversely, complex 1 exhibited the highest TON of 30,066 for HER when quantum dots were employed as the photosensitizer.

An overview on Argentina Energy Market

Abstract The article presents Argentina energy market. It is made an overview on legal framework, regulatory authorities and transport and distribution system for electricity and oil and gas sector. Finally it is presented the today market of energy and renewables sector. Argentina's energy landscape is a dynamic tapestry woven with various legal frameworks, regulatory authorities, and transportation and distribution systems for electricity and oil and gas sectors. The country's energy market, encompassing both conventional and renewable sources, presents a compelling narrative of challenges and opportunities. Navigating the complexities of Argentina's energy market requires a comprehensive understanding of the legal framework, regulatory landscape, and transportation and distribution systems. The interplay of conventional and renewable energy sources further adds to the dynamic nature of the sector. As Argentina strives to secure a sustainable and affordable energy future, it will need to address the challenges while capitalizing on the opportunities that lie ahead.

Experimental Study an Effect of Photovoltaic (PV) Arrangement on Performance of 150 wp Solar Power Plant

Due to depletion of conventional fuel and also due to increasing global warming in last several years, the search of alternative and renewable energy increases remarkably worldwide. Many sources of alternative energy have been explored to substitute conventional source of energy by numerous researchers. Nowadays, another promising alternative energy got increasing attention is solar energy. As a matter of fact, in renewable sources, solar power contribution is so high when compared with other sources. The present study aims to figure out an effect of photovoltaic (PV) arrangement on performance of the solar system at three different configurations solar panel, i.e. standalone 150 wp (Model I), 100 wp + 50 wp (Model II), and 3 x 50 wp (Model II). The results show that the model I able to generate average power about 121.57 W which means that the model has an efficiency of 83.05% respect to the capacity of the PV.

Managing the kinetic energy of descending greywater in tall buildings and converting them into a valuable source

Harnessing energy from descending greywater (GW) in tall buildings (TBs) is an innovative concept that combines water management with renewable energy generation and applying simulation methods. This study proposes a novel approach to enhancing sustainable energy recovery in TBs by capitalizing on the kinetic energy inherent in descending GW. Greywater, derived from non-toilet fixtures such as showers, bathroom sinks, and washing machines, offers a readily accessible source of potential energy due to its gravity-driven flow through the plumbing system. This gravitational potential energy could feasibly be converted into useable electricity through the incorporation of specialized energy-recovery mechanisms, such as turbines, hydroelectric generators, and piezoelectric devices. The study addresses the technical, economic and environmental aspects of implementing this idea in TBs. It describes the challenges of system integration, maintenance requirements and adherence to regulatory standards, as well as the potential benefits in terms of water conservation and reduced reliance on conventional energy sources, through a comprehensive analysis encompassing modeling, experimental validation and feasibility assessments. The research offers insights into the potential viability of harnessing downward-flowing GW as an alternative and sustainable green energy resource.

Novel approach to remote rural heating: Direct coupled photovoltaic electric heater underfloor heating system with phase change materials

Limited access to grids and the unavailability of traditional energy sources present significant challenges to effective heating in remote rural. This paper proposes a direct coupled photovoltaic electric heater underfloor heating system with phase change materials (direct coupled PVEH-UFHs), which eliminates the reliance on the power grid or conventional energy sources for heating in remote areas. The model of the direct coupled photovoltaic electric heating system (direct coupled PVEHs) and the building model with PCM floor were created and the accuracy of the direct coupled PVEHs model was verified experimentally. The study proposes using the total heating achievement rate (THAR) as the evaluation index and identifies the critical parameters affecting the system performance through sensitivity analysis. The results indicate that the photovoltaic capacity factor (PVCF), PCMs thickness and melting temperature are the key parameters affecting the heating performance of the system. The recommended 1.4 PVCF and PCM melting temperature of 294 K. The minimum payback time for system configuration that achieves 90 % THAR is 16.2 years. In summary, this paper proposes a design method and evaluation criteria for direct coupled PVEH-UFHs suitable for energy-efficient heating in remote areas.

Power Quality Study in Distribution Networks with High Penetration of Renewable Energies using Real-Time Simulation

Introduction: The power supplied to the load through the distribution network comes mainly from conventional energy sources. However, a transformation is being made towards sustainable and efficient electricity networks, which incorporate distributed renewable energy sources and closer to consumption. This process has led to the investigation of the effects that the inclusion of distributed energy resources brings, which have shown power quality issues. However, more studies are required to show more detailed effects and the use of new tools such as real-time simulation. Objective: This paper uses real-time simulation to evaluate the impact on the power quality produced by integrating distributed energy resources (DER) into a distribution network. Method: The IEEE 13-node test feeder system was used to evaluate voltage harmonics, current harmonics, flicker, and DC injection based on the IEEE 1547-2018, IEEE 519-2014, and the NTC 5001-2008 standards. The feeder test system was implemented in the Hypersim software and used to run real-time simulations. Results: The results show that integrating distributed energy resources into the network produces a high impact on the current harmonics of the network. Conclusions: The DC injection phenomenon presents a medium impact, and flickers and voltage harmonics present a lower impact.

ANALISIS ALIRAN UDARA PADA PIPA KOMPOR BURNER

A used oil burner stove is a type of stove that uses used oil as fuel to produce fire and heat which is used in the cooking process. This concept is more commonly found in areas with limited access to conventional energy sources such as electricity or gas. Apart from that, there is a blower which has an important function to maintain sufficient and high-speed air flow towards the combustion axis, thereby helping to increase oil burning efficiency. This test was carried out using Solidworks software with the CFD or Computational Fluid Dynamic feature which has the function of analyzing fluid flow on an object by entering the required parameters. In this paper, a burner stove pipe with an initial cross-sectional area of 2" inches and a final cross-sectional area of 1/2" inches is used where an initial velocity input is given with independent variables of 2 m/s, 4 m/s and 6 m/s and the output is obtained or The results on the stove burner pipe were 17.9 m/s, 37.3 m/s and 54.6 m/s.

An eco-friendly approach for bioelectricity production through microbial fuel cell using Musa acuminata as waste biomass

With the increasing population and industrialization, the demand of electricity is increasing day-by-day and high energy demands have adverse effects on fossil fuels consumption. The sustainable development goal (SDG) 7 focuses on green energy. Due to this, global attention is shifted from conventional sources to non conventional energy sources such as solar energy, wind energy, waste biomass, etc. This work explores the feasibility of a microbial fuel cell for bio-electricity production. The effect of different catholytes on bio electricity production is assessed. This research includes the fabrication of a H-shaped double chambered microbial fuel cell using two containers of 2 L each. Both the containers were connected with an agar salt bridge. The bioelectricity was produced from banana peel waste using potassium dichromate and potassium ferricyanide as catholyte and zinc rod and copper plate as electrodes. With potassium dichromate, the maximum value of voltage and current was found as 0.20 V and 0.112 mA respectively, while in case of potassium ferricyanide the maximum voltage and current obtained was 0.42 V and 0.55 mA respectively at 0.1 M concentration of catholyte. Substrates like glucose (10 % by weight) and sodium acetate (5 % by weight) was added in the banana peel slurry so as to make the microbial fuel cell more efficient. Further, impact of increase in potassium ferricyanide concentration from 0.1 to 0.5 M concentration on the generation of electricity was analysed and it was found that with increase in concentration of catholyte, voltage and current enhanced. The maximum voltage, current and power density found by increasing concentration of potassium ferricyanide from 0.1 to 0.5 M was 0.9 V, 3.36 mA and 1.055 W/m2. This study concludes that potassium ferricyanide is better oxidising agent than potassium dichromate. Microbial fuel cell can be a promising technology for bioelectricity production using banana peel waste.

Comparative Review on the Production and Purification of Bioethanol from Biomass: A Focus on Corn

In the contemporary era, conventional energy sources like oil, coal, and natural gas overwhelmingly contribute 89.6% to global CO2 emissions, intensifying environmental challenges. Recognizing the urgency of addressing climate concerns, a pivotal shift towards renewable energy, encompassing solar, wind, and biofuels, is crucial for bolstering environmental sustainability. Bioethanol, a globally predominant biofuel, offers a versatile solution, replacing gasoline or integrating into gasoline–ethanol blends while serving as a fundamental building block for various valuable compounds. This review investigates the dynamic landscape of biomass generations, drawing insightful comparisons between the first, second, third, and fourth generations. Amid the drive for sustainability, the deliberate focus on the initial generation of biomass, particularly corn, in bioethanol production is grounded in the current dependence on edible crops. The established utilization of first-generation biomass, exemplified by corn, underscores the necessity for a comprehensive examination of its advantages and challenges, allowing for a nuanced exploration of existing infrastructure and practices. To produce bioethanol from corn feedstock, various milling methods can be employed. Thus, this paper delves into a comparative assessment of dry-milling and wet-milling processes scrutinizing their efficiency, environmental impact, and economic feasibility.

Belief Reliability Modeling Method for Wind Farms Considering Two-Directional Rotor Equivalent Wind Speed

Compared to conventional energy sources, wind power is a clean energy source with high intermittence and uncertainty. As a system that converts wind energy into electricity, wind farms inevitably face severe reliability issues. In this paper, based on reliability theory, a new reliability modeling method for wind farms is proposed. Firstly, a belief reliability model for wind farms is constructed. Then, a power generation model based on two-directional rotor equivalent wind speed is established to represent the wind farm performance in the belief reliability model. Finally, several numerical studies are conducted to verify the power generation model under different wind speeds and directions, to demonstrate the belief reliability model with different levels of uncertainty, and to compare the belief reliability considering two-directional rotor equivalent wind speed with other methods.

Exploring the Genetic Wealth of Sunflower (Helianthus annuus L.): A Comprehensive Review on Its Products and By-Products

Sunflower stands out as a significant oilseed crop, pivotal not only in the production of edible oil and biofuels but also in the formulation of nutritious animal feed. Particularly noteworthy are the diverse opportunities presented by sunflower by-products. From the nutrient-rich sunflower oil cake to the versatile sunflower wax utilized in cosmetics and pharmaceuticals, the potential applications are manifold. Additionally, the burgeoning interest in sunflower-derived biofuels as sustainable alternatives to conventional energy sources highlights the crop's growing importance in modern agriculture. However, to meet the evolving demands sustainably, an in-depth analysis of sunflower cultivation practices and nutrient management strategies for optimal productivity is imperative. This review provides a comprehensive overview of sunflower cultivation techniques, processing methods, and avenues for value addition across various sectors. Renowned for its vibrant flowers and seeds brimming with high-quality oil, sunflower holds a significant economic value. Its oil, rich in beneficial unsaturated fatty acids and essential vitamins, has garnered acclaim for its health benefits, including cholesterol reduction and cardiovascular health promotion. Thriving primarily in warm climates and exhibiting resilience to drought conditions, sunflowers have witnessed a surge in demand for their sprouts, roasted seeds, oil, and even agricultural tourism ventures. With sunflower seeds and oil serving as essential components in integrated production systems, the scope for creating diverse food and non-food products continues to expand. By offering this comprehensive synthesis, this review aims to guide stakeholders towards maximizing the utilization of sunflowers across multiple domains.

Grid Synchronization in a 3-Phase Inverter using Double Integration Method

Distributed renewable energy sources (DRESs) have additional benefits compared with conventional fossil fuel-based energy sources. These sources are connected to the utility grid using a suitable synchronization method. It requires accurate information on grid voltage magnitude and phase angle. But the presence of harmonics, DC Offset, and voltage unbalances makes the synchronization process more challenging. Conventionally synchronous reference frame (SRF)- PLL is implemented for this purpose, however, it has a problem with 100Hz ripple during distorted grid conditions. A double integration method (DIM) is administered for the synchronization of a 3-phase inverter under non-ideal grid conditions. It is important for DIM implementation to remove the DC offset or integrating constants of pure integrators without involving any phase shift. This method is also compared with conventional SRF-PLL based on mathematical modelling and simulations using a MATLAB/Simulink toolbox. The results are verified based on ideal and non–ideal grid conditions and also tested on grid-connected 3-phase Inverter.

Another look at energy consumption and environmental sustainability target through the lens of the load capacity factor: Accessing evidence from MINT economies

AbstractThe relationship between energy utilization and the environment is crucial in an era of environmental concerns by global economies and rising energy consumption. Emerging economies such as Mexico, Indonesia, Nigeria, and Turkey (hereafter, MINT) face complex trade‐offs between economic growth and environmental sustainability. Strengthening this study are the UN Sustainable Development Goals prepositions on access to clean and alternative energy, decent economic growth, responsible production and consumption and climate action (UN‐SDGs‐7, 8, 12, and 13). The present study examines the environmental Kuznets curve (EKC) hypothesis for MINT economies within the framework of the load capacity factor (LCF). The article leverages panel econometrics to operationalize the relationship between study variables. Empirical findings show that the present study fails to confirm the presence of EKC. Thus, it implies that the MINT economies are at their first stage of accelerated economic growth which might result in an augmented ecological footprint and exert pressure on natural resources, as indicated by the observed negative outcome. Furthermore, there is a positive and significant relationship between renewable energy consumption (RENENG) and LCF. It implies that a 1% increase in RENENG leads to an increase in LCF of 0.70%. These outcomes indicate that the level of RENENG in MINT economies is not sufficient to mitigate climate change issues. Thus, from a policy perspective, there is a need for change in the MINT nations' energy portfolio mix, such as the need to switch from conventional energy sources (fossil fuels) to renewable energy sources, including solar, wind, photovoltaic and hydropower, which usually have a smaller negative impact on the environment. Furthermore, there is a need for investment in new and green energy technologies in the countries investigated to arrive at a clean and better ecosystem as desired. More insight is outlined in the concluding section.

Progress Of Low-Temperature Carbonization of Cellulose as Anode Material for Sodium-Ion Batteries

With the increasingly serious environmental issues brought by the use of conventional fossil energy sources, and under the idea of "carbon peak and carbon neutral" put forward by China, it has been a global consensus to drive the transition of the energy consumption framework from conventional fossil energy sources to low-carbon, clean reproducible energy sources, and associated energy preservation technologies. So far, secondary battery systems as stable and efficient clean energy storage have been the focus of attention, and the most important energy storage devices are lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs), which are also potential battery systems under recent research. Nevertheless, the scarcity and grossly uneven allocation of lithium resources as well as the security problems of lithium batteries have limited the further growth of LIBs. Due to these problems, the scientific community has been back to sodium-ion battery studies. By comparing with lithium-ion batteries, sodium resources for sodium-ion batteries are cheaper, richer, and safer, so the social demand for sodium-ion batteries continues to increase, but the larger the ionic radius of sodium ions, the poorer the reversible capacity, the shorter the life span and other problems still exist, and the development of high-performance anode materials is an effective method to solve the core problems of sodium-ion batteries, cellulose-based hard carbon materials have a green preparation process, favorable ion Cellulose-based hard carbon material is a potential anode material for sodium-ion batteries with the green preparation process, beneficial ion transport channel and special porous framework.

A novel method for hydrogen synthesis in natural gas reservoirs

Hydrogen has been proven as a promising energy resource for a clean and sustainable future. However, the complete replacement of conventional hydrocarbon energy sources poses a challenge due to their widespread industrial utilization. Despite the gradual depletion of petroleum and natural gas reserves, they continued to serve as primary energy sources for many decades. But what if we could repurpose these hydrocarbons? Currently, fossil fuels that are both non-renewable and environmentally unfriendly are directly used for energy generation. Instead, we could convert hydrocarbons into a significantly cleaner alternative – hydrogen. This process implies in situ hydrogen generation even before hydrocarbons are recovered from a reservoir without releasing greenhouse gases into the atmosphere. In this context, we explore the conversion of methane into hydrogen in the gas reservoir with zero oil saturation via steam methane reforming initiated by in situ gas combustion. In the experimental model, different rock porous media were utilized and the process parameters such as temperature and the steam-to-methane ratio were varied. The outcome reveals a range of variations, each yielding different concentrations of hydrogen produced depending on these adjustable parameters. Our findings suggest the incredible potential for underground hydrogen generation in natural gas reservoirs. This approach holds great promise as a leading candidate for the foreseeable future, benefiting from the synergy of the fossil fuel industry and an innovative hydrogen production technology.

A scientometrics analysis and visualization of the ecological impact of photovoltaic projects

The topic of global climate change has heated up in recent years, and other environmental and energy-related challenges have been continuously gaining attention. At the same time, the concept of sustainable development and carbon-neutral strategies have emerged. Photovoltaic electricity is strongly promoted by pertinent policies as a high-quality substitute for conventional energy sources. Meanwhile, the potential ecological impacts of photovoltaic (PV) projects should also be noted. Currently, there is a lack of comprehensive research on the ecological impact of photovoltaic projects. It is of great necessity to summarize the research status and future trends of this topic from the perspective of a literature review. Therefore, a scientometrics analysis and visualization of the ecological impact of photovoltaic projects was conducted in this study, using CiteSpace as the visualization tool. Web of Science and Scopus were selected as the databases, and the retrieved articles were analyzed using co-occurrence and cluster analysis to discover hot research subjects and evolving trends, as well as to examine institutional, national, and author collaborations. The results help in the present study field of the ecological effect of photovoltaic projects in identifying and understanding trends and patterns. This study offers theoretical support for PV site selection and ecological protection nearby. It can also motivate academics, politicians, institutions, and governments to formulate ecologically friendly roadmaps and regimes in balancing PV development and ecological protection.

On identifying suitable hydrogen power plant location under [formula omitted]-spherical fuzzy hypersoft matrix structures

In recent decades, the prime objective of the energy sector has been to replace conventional energy sources with renewable energy sources such as hydrogen power, solar energy, etc. The objective of the present communication is to computationally locate the best site for the establishment of the hydrogen power plant given the various uncertainty parameters in terms of inexact and incomplete information. The uncertainty components of the information are well dealt with by the incorporation of T-spherical fuzzy hypersoft information. In accordance, we present the new concept of T-spherical fuzzy hypersoft matrix (TSFHSM) with different matrix-theoretic structured possibilities having useful computational setups. Some standard matrix operations with their algebraic properties have also been studied. Next, the structure of the proposed matrix has been utilized in presenting two new methodologies for the decision-making selection problems — one with the help of choice/weighted choice T-spherical fuzzy hypersoft matrices and the other with the value & score T-spherical fuzzy hypersoft matrices. Further, an illustrative example where the set of sites for the selection of hydrogen power plants has been computationally studied with the help of the presented novel algorithms given the available criteria. The efficacy of the proposed algorithms and their implementations have been discussed along with a comparative analysis, advantages and a characteristic comparison table.

Achieving environmental sustainability goals through capitalizing on renewable energy channels: Role of green finance, resources productivity and geopolitical situation in the MENA region

Environmental sustainability is essential to the country's financial position and economic growth. Geopolitical situations and green activities significantly contribute to enhancing sustainable development goals. The purpose of this study is to evaluate the impact of green finance, investment in renewable energy sources and geopolitical risk on the environmental sustainability of the Middle East and North America (MENA) region over the period 2000–2021. When using a cross‐sectional dependence autoregressive distributed lag model (CS‐ARDL), it is discovered that a rise in geopolitical risk will decrease environmental performance in the form of carbon dioxide emission. At the same time, the other factors (green finance and investment in renewable energy) have a positive relationship with sustainability. This observation can be ascribed to the association between increased geopolitical risk and the inclination of crude oil consumers, who are most affected by such risk, to contemplate renewable energy as an alternative to conventional energy sources. This finding could also be attributed to the fact that clean energy is becoming more affordable. In addition, the augmented mean group model findings provide more evidence that a negative linkage is found between geopolitical risk and environmental sustainability. The findings have repercussions for regulators as well as investors who are active in the renewable energy markets.

Geothermal Heat Pump for Space Cooling and Heating in Kuwaiti Climate

Kuwait stands as one of the hottest locations globally, experiencing scorching temperatures that can soar to 50 °C during the summer months. Conversely, in the winter months of December and January, temperatures may plummet to less than 10 °C. Maintaining a comfortable temperature indoors necessitates a substantial amount of energy, particularly during the scorching summer seasons. In Kuwait, most of the electrical energy required for functions such as air conditioning and lighting is derived from fossil fuel resources, contributing to escalating air pollution and global warming. To reduce dependence on conventional energy sources for heating and cooling, this article presents a case study to explore the potential of using geothermal energy for space heating and cooling in Kuwait. The case study involves utilizing a geothermal heat pump (water-sourced heat pump) in conjunction with a vertical-borehole ground heat exchanger (VBGHE). The mentioned system is deployed to regulate the climate in a six-floor apartment block comprising a small two-bedroom apartment on each level, each with a total floor area of 57 m2. Two geothermal heat pumps, each with a cooling capacity of 2.58 kW and a heating capacity of 2.90 kW, connected to two vertical-borehole heat exchangers, were deployed for each apartment to maintain temperatures at 22 °C in winter and 26 °C in summer. The findings indicate that the estimated annual energy loads for cooling and heating for the apartment block are 42,758 kWh and 113 kWh, respectively. The corresponding electrical energy consumption amounted to 9294 kWh for space cooling and 113 kWh for space heating. The observed peak cooling load was approximately 9300 kJ/h (2.58 kW) per apartment, resulting in a power density of 45 W/m2. Moreover, the HP system achieved a 22% reduction in annual electric energy consumption compared to conventional air conditioning systems. This reduction in electric energy usage led to an annual CO2 reduction of 6.6 kg/m2.