Dynamic Modelling of LNG Powered Combined Energy Systems in Port Areas

Liquefied Natural Gas (LNG) is a crucial resource to reduce the environmental impact of fossil-fueled vehicles, especially with regards to maritime transport, where LNG is increasingly used for ship bunkering. The present paper gives insights on how the installation of LNG tanks inside harbors can be capitalized to increase the energy efficiency of port cities and reduce GHG emissions. To this purpose, a novel integrated energy system is introduced. The Boil Off Gas (BOG) from LNG tanks is exploited in a combined plant, where heat and power are produced by a regenerated gas turbine cycle; at the same time, cold exergy from LNG regasification contributes to an increase in the efficiency of a vapor compression refrigeration cycle. In the paper, the integrated energy system is simulated by means of dynamic modeling under daily variable working conditions. Results confirm that the model is stable and able to determine the time behavior of the integrated plant. Energy saving is evaluated, and daily trends of key thermophysical parameters are reported and discussed. The analysis of thermal recovering from the flue gases shows that it is possible to recover a large energy share from the turbine exhausts. Hence, the system can generate electricity for port cold ironing and, through a secondary brine loop, cold exergy for a refrigeration plant. Overall, the proposed solution allows primary energy savings up to 22% when compared with equivalent standard technologies with the same final user needs. The exploitation of an LNG regasification process through smart integration of energy systems and implementation of efficient energy grids can contribute to greener energy management in harbors.

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REA: Resource Exergy Analysis - A basic guideline for application focusing on energy systems evaluation

10.21203/rs.3.rs-979554/v3 ◽

2022 ◽

Author(s):

Andrej Jentsch

Keyword(s):

Global Economy ◽

Fossil Fuels ◽

Exergy Analysis ◽

Ghg Emissions ◽

Energy Systems ◽

Energy System ◽

Primary Energy ◽

Resource Consumption ◽

Decision Makers ◽

Climate Targets

Abstract This publication provides a basic guideline to the application of Resource Exergy Analysis (REA) with a focus on energy systems evaluation. REA is a proven application of exergy analysis to the field of technology comparison.REA aims to help decision makers to obtain an indicator in addition to GHG emissions, that is grounded in science, namely Resource Consumption.Even if an energy system uses GHG-free energy increased Resource Consumption likely increases the need for fossil fuels and thus GHG emissions of the global economy. Resource Consumption can replace the less comprehensive Primary Energy Consumption as an indictor and reduce the risk of suboptimal decisions.Evaluating energy systems using REA is key to ensure that climate targets are reached in time.

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Numerical Study of a Micro Gas Turbine Integrated With a Supercritical CO2 Brayton Cycle Turbine

Volume 8: Microturbines, Turbochargers, and Small Turbomachines; Steam Turbines ◽

10.1115/gt2018-76656 ◽

2018 ◽

Author(s):

Fabrizio Reale ◽

Vincenzo Iannotta ◽

Raffaele Tuccillo

Keyword(s):

Gas Turbines ◽

Waste Heat ◽

Numerical Study ◽

Organic Rankine Cycle ◽

Energy Systems ◽

Rankine Cycle ◽

Energy System ◽

Small Scale ◽

Brayton Cycle ◽

Integrated Energy System

The primary need of reducing pollutant and greenhouse gas emissions has led to new energy scenarios. The interest of research community is mainly focused on the development of energy systems based on renewable resources and energy storage systems and smart energy grids. In the latter case small scale energy systems can become of interest as nodes of distributed energy systems. In this context micro gas turbines (MGT) can play a key role thanks to their flexibility and a strategy to increase their overall efficiency is to integrate gas turbines with a bottoming cycle. In this paper the authors analyze the possibility to integrate a MGT with a super critical CO2 Brayton cycle turbine (sCO2 GT) as a bottoming cycle (BC). A 0D thermodynamic analysis is used to highlight opportunities and critical aspects also by a comparison with another integrated energy system in which the waste heat recovery (WHR) is obtained by the adoption of an organic Rankine cycle (ORC). While ORC is widely used in case of middle and low temperature of the heat source, s-CO2 BC is a new method in this field of application. One of the aim of the analysis is to verify if this choice can be comparable with ORC for this operative range, with a medium-low value of exhaust gases and very small power values. The studied MGT is a Turbec T100P.

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INDUSTRIAL APPLICATION OF A SECOND-LAW MODELLING PROCEDURE

Transactions of the Canadian Society for Mechanical Engineering ◽

10.1139/tcsme-1988-0022 ◽

1988 ◽

Vol 12 (3) ◽

pp. 153-157

Author(s):

JOHN W. CHINNECK

Keyword(s):

Energy Consumption ◽

Energy Savings ◽

Energy Systems ◽

Energy System ◽

Second Law ◽

Additional Energy ◽

Industrial Plants ◽

Plant Manager ◽

Modelling Procedure ◽

Modelling Techniques

The energy systems in large industrial plants are often very complex involving hundreds of items of equipment such as furnaces, turbines, boilers, generators, etc., and numerous energy forms such as oil, natural gas, steam, electricity and so on. It is usually not obvious how to operate the system to minimize energy consumption, thereby minimizing fuel expenditures. Computer models can be effective tools for the plant manager in tackling this problem. This paper presents the results of the application of a new modelling procedure to the energy system in an existing Canadian petrochemicals plant. The new procedure identified an estimated $600,000 per annum in additional energy savings over other modelling techniques that had been applied to the plant. The procedure includes second-law measures in a convenient and easily-applied form.

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Evaluation of Integrated Energy System in Airports Based on Comprehensive Weighting Method

E3S Web of Conferences ◽

10.1051/e3sconf/202124501022 ◽

2021 ◽

Vol 245 ◽

pp. 01022

Author(s):

Ji Jiayin ◽

Chen Kang

Keyword(s):

Heat Pump ◽

Energy System ◽

Primary Energy ◽

Pollutant Emissions ◽

Energy Storage Devices ◽

Entropy Weight ◽

Analytic Hierarchy ◽

Weighting Method ◽

Distributed Energy System ◽

Integrated Energy System

Airport is a typical integrated energy system in a park with various energy requirements. In this paper, a multi-dimensional quantitative analysis of system performance indicators was conducted by using a comprehensive weighting method based on the analytic hierarchy process (AHP) and anti-entropy weight method. A distributed energy system evaluation matrix model was used to evaluate and compare different integrated energy designs. The results showed that electric boilers would increase the primary energy ratio and primary energy consumption than the ones caused by gas boilers. Also, energy storage devices could significantly decrease pollutant emissions of integrated energy systems but would increase investment costs and reduce the economic indicators of system solutions. In a word, the configuration with ice storage, combined cooling, heating and power (CCHP), gas boiler, ground source heat pump (GSHP), air source heat pump (ASHP), and absorption chiller had the best evaluation indicators.

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The Challenge of Climate Change—Complete Energy Systems Transformation: No Nuclear, No Net Zero

Nuclear Law ◽

10.1007/978-94-6265-495-2_6 ◽

2022 ◽

pp. 85-140

Author(s):

Timothy Stone

Keyword(s):

National Policy ◽

Energy Systems ◽

Energy System ◽

Primary Energy ◽

Low Carbon ◽

Policy Makers ◽

Call To Action ◽

Net Zero ◽

Primary Energy Supply ◽

Systems Transformation

AbstractTo achieve Net Zero, natural gas, gasoline, diesel, and fuel oils must be replaced with another source. However, most of the current low-carbon energy sources will also need to be replaced as almost none have more than about 25 years remaining of useful life. The pace and scale of the needed change is unprecedented: almost the whole of the world’s primary energy supply must be replaced. The (re)development of the entire energy system is inherently a sovereign risk and it can only be governments who set national energy policy. There is no doubt that markets will continue to play a part in future energy systems, but at the top level, the pace and scale of change to achieve Net Zero is simply far too fast for markets to adapt properly. This chapter is a call to action to the national policy makers and presents this challenge as an opportunity for creating higher-quality jobs and potentially highly attractive and long-dated investment options. The chapter also outlines some risks, including political indecisiveness and policy volatility as potential impediments to making the most of this opportunity and achieving the Net Zero.

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Multi-Time Scale Economic Optimization Dispatch of the Park Integrated Energy System

Frontiers in Energy Research ◽

10.3389/fenrg.2021.743619 ◽

2021 ◽

Vol 9 ◽

Author(s):

Peng Li ◽

Fan Zhang ◽

Xiyuan Ma ◽

Senjing Yao ◽

Zhuolin Zhong ◽

...

Keyword(s):

Renewable Energy ◽

Time Scales ◽

Time Scale ◽

Energy Systems ◽

Energy System ◽

Optimal Operation ◽

Utilization Efficiency ◽

Integrated Energy System ◽

Operation Cost ◽

Different Time Scales

The park integrated energy system (PIES) plays an important role in realizing sustainable energy development and carbon neutral. Furthermore, its optimization dispatch can improve the energy utilization efficiency and reduce energy systems operation cost. However, the randomness and volatility of renewable energy and the instability of load all bring challenges to its optimal operation. An optimal dispatch framework of PIES is proposed, which constructs the operation models under three different time scales, including day-ahead, intra-day and real-time. Demand response is also divided into three levels considering its response characteristics and cost composition under different time scales. The example analysis shows that the multi-time scale optimization dispatch model can not only meet the supply and demand balance of PIES, diminish the fluctuation of renewable energy and flatten load curves, but also reduce the operation cost and improve the reliability of energy systems.

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Holistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability

Infrastructures ◽

10.3390/infrastructures6110150 ◽

2021 ◽

Vol 6 (11) ◽

pp. 150

Author(s):

Kai Hoth ◽

Tom Steffen ◽

Béla Wiegel ◽

Amine Youssfi ◽

Davood Babazadeh ◽

...

Keyword(s):

Energy Management ◽

Dynamic Models ◽

Energy Systems ◽

Energy System ◽

Optimal Operation ◽

Distributed Resources ◽

Holistic Model ◽

Future System ◽

Integrated Energy System ◽

Operational Concept

The intermittent energy supply from distributed resources and the coupling of different energy and application sectors play an important role for future energy systems. Novel operational concepts require the use of widespread and reliable Information and Communication Technology (ICT). This paper presents the approach of a research project that focuses on the development of an innovative operational concept for a Smart Integrated Energy System (SIES), which consists of a physical architecture, ICT and energy management strategies. The cellular approach provides the architecture of the physical system in combination with Transactive Control (TC) as the system’s energy management framework. Independent dynamic models for each component, the physical and digital system, operational management and market are suggested and combined in a newly introduced co-simulation platform to create a holistic model of the integrated energy system. To verify the effectiveness of the operational concept, energy system scenarios are derived and evaluation criteria are suggested which can be employed to evaluate the future system operations.

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Techno-Economic Evaluation of Interconnected Nuclear-Renewable Micro Hybrid Energy Systems with Combined Heat and Power

Energies ◽

10.3390/en13071642 ◽

2020 ◽

Vol 13 (7) ◽

pp. 1642 ◽

Cited By ~ 4

Author(s):

Hossam A. Gabbar ◽

Muhammad R. Abdussami ◽

Md. Ibrahim Adham

Keyword(s):

Fossil Fuel ◽

Renewable Energy Sources ◽

Ghg Emissions ◽

Energy Systems ◽

Energy System ◽

Combined Heat And Power ◽

Small Scale ◽

Hybrid Energy ◽

Hybrid Energy Systems ◽

The Impact

Renewable energy sources (RESs) play an indispensable role in sustainable advancement by reducing greenhouse gas (GHG) emissions. Nevertheless, due to the shortcomings of RESs, an energy mix with RESs is required to support the baseload and to avoid the effects of RES variability. Fossil fuel-based thermal generators (FFTGs), like diesel generators, have been used with RESs to support the baseload. However, using FFTGs with RESs is not a good option to reduce GHG emissions. Hence, the small-scale nuclear power plant (NPPs), such as the micro-modular reactor (MMR), have become a modern alternative to FFTGs. In this paper, the authors have investigated five different hybrid energy systems (HES) with combined heat and power (CHP), named ‘conventional small-scale fossil fuel-based thermal energy system,’ ‘small-scale stand-alone RESs-based energy system,’ ‘conventional small-scale fossil fuel-based thermal and RESs-based HES,’ ‘small-scale stand-alone nuclear energy system,’ and ‘nuclear-renewable micro hybrid energy system (N-R MHES),’ respectively, in terms of net present cost (NPC), cost of energy (COE), and GHG emissions. A sensitivity analysis was also conducted to identify the impact of the different variables on the systems. The results reveal that the N-R MHES could be the most suitable scheme for decarbonization and sustainable energy solutions.

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Research on Battery Energy Storage as Backup Power in the Operation Optimization of a Regional Integrated Energy System

Energies ◽

10.3390/en11112990 ◽

2018 ◽

Vol 11 (11) ◽

pp. 2990 ◽

Cited By ~ 12

Author(s):

Jianfeng Li ◽

Dongxiao Niu ◽

Ming Wu ◽

Yongli Wang ◽

Fang Li ◽

...

Keyword(s):

Energy Storage ◽

Simulation Optimization ◽

Energy Systems ◽

Energy System ◽

Power Source ◽

Battery Energy Storage ◽

Operation Optimization ◽

Integrated Energy Systems ◽

Integrated Energy System ◽

Battery Energy

Recently, integrated energy systems have become a new type of energy supply model. It is clear that integrated energy systems can improve energy efficiency and reduce costs. However, the use of a battery energy storage system (BESS) as a backup power source will affect the operating costs of a regional integrated energy system (RIES) in different situations. In this paper, a regional integrated energy system including wind turbines, photovoltaics, gas turbines and battery energy storage was introduced. In order to obtain the minimum operation cost, an operation optimization model was built. The schedule plans of each unit were optimized by a moth flame optimization (MFO) algorithm. Finally, three different scenarios were proposed for the simulation optimization. The simulation optimization results show that when the BESS is used as a backup power source, the operating cost of the system and the resulting pollutant emissions are less than the diesel generator (DG) set. Therefore, it is worthwhile to use BESS instead of DG as the backup power source in RIES.

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What Will Make Energy Systems Sustainable?

Sustainability ◽

10.3390/su10072537 ◽

2018 ◽

Vol 10 (7) ◽

pp. 2537 ◽

Cited By ~ 2

Author(s):

Angela Köppl ◽

Stefan Schleicher

Keyword(s):

Value Chain ◽

Electric Energy ◽

Energy Systems ◽

Spillover Effects ◽

Energy System ◽

Radical Change ◽

Primary Energy ◽

Lessons Learned ◽

Sustainable Energy Systems ◽

Development Goals

Despite the success of the German Energiewende in increasing the production of electricity from renewables and the positive global spillover effects of renewable technologies, one of the lessons learned is the insight that simply shifting to renewables and recommending improving energy efficiency is not sufficient to lower greenhouse gas emissions. Combined with the expected radical change of technologies, this requires a more profound understanding of our energy systems. Therefore, in contrast to many conventional energy economy approaches, we propose a deepened structural analysis that covers the full energy value chain from the required functionalities for mechanical, thermal and specific electric energy services via application and transformation technologies up to primary energy. This deepened structural approach opens and substantially enhances our understanding of policy designs that are compatible with the Paris Agreement and Sustainable Development Goals. We discover the essential role of four energy grids, namely for electricity, heat, gas, and information as the key for integrating all components of a newly structured energy system. Consequently, we conclude that policy strategies focusing on individual components of an energy system like shifting to renewables may, from a comprehensive perspective on more sustainable energy systems, prove even counterproductive.

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