A Comparison of Different District Integration for a Distributed Generation System for Heating and Cooling in an Urban Area

Casisi, Melchiorre; Buoro, Dario; Pinamonti, Piero; Reini, Mauro

doi:10.3390/app9173521

Cited by 12 publications

(19 citation statements)

References 29 publications

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“…Therefore, the study highlights the potential heat sources and the match with the small and medium size, low temperature CCHP technologies that will be still of interest, even in a future scenario dominated by RE resources and massive electrification, showing that reductions in the LCOE and LCOH can be achieved through a wider integration of the thermal products. Full exploitation of the potential benefit of CHP could be reached only by means of an optimization procedure of CHP units, jointly with the DH local grids [145,146], in the considered economic and energy-demand scenarios.…”

Section: Discussionmentioning

confidence: 99%

A Review of Small–Medium Combined Heat and Power (CHP) Technologies and Their Role within the 100% Renewable Energy Systems Scenario

et al. 2021

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The energy transition towards a scenario with 100% renewable energy sources (RES) for the energy system is starting to unfold its effects and is increasingly accepted. In such a scenario, a predominant role will be played by large photovoltaic and wind power plants. At the same time, the electrification of energy consumption is expected to develop further, with the ever-increasing diffusion of electric transport, heat pumps, and power-to-gas technologies. The not completely predictable nature of the RES is their well-known drawback, and it will require the use of energy storage technologies, in particular large-scale power-to-chemical conversion and chemical-to-power re-conversion, in view of the energy transition. Nonetheless, there is a lack in the literature regarding an analysis of the potential role of small–medium CCHP technologies in such a scenario. Therefore, the aim of this paper is to address what could be the role of the Combined Heat and Power (CHP) and/or Combined Cooling Heat and Power (CCHP) technologies fed by waste heat within the mentioned scenario. First, in this paper, a review of small–medium scale CHP technologies is performed, which may be fed by low temperature waste heat sources. Then, a review of the 100% RE scenario studied by researchers from the Lappeenranta University of Technology (through the so-called “LUT model”) is conducted to identify potential low temperature waste heat sources that could feed small–medium CHP technologies. Second, some possible interactions between those mentioned waste heat sources and the reviewed CHP technologies are presented through the crossing data collected from both sides. The results demonstrate that the most suitable waste heat sources for the selected CHP technologies are those related to gas turbines (heat recovery steam generator), steam turbines, and internal combustion engines. A preliminary economic analysis was also performed, which showed that the potential annual savings per unit of installed kW of the considered CHP technologies could reach EUR 255.00 and EUR 207.00 when related to power and heat production, respectively. Finally, the perspectives about the carbon footprint of the CHP/CCHP integration within the 100% renewable energy scenario were discussed.

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Section: Discussionmentioning

confidence: 99%

A Review of Small–Medium Combined Heat and Power (CHP) Technologies and Their Role within the 100% Renewable Energy Systems Scenario

et al. 2021

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“…The case they studied in Northern Italy demonstrated how the storage operation could allow solar energy to cover total demand. Solar thermal energy integration has also been studied in an industrial sector [28,29] using MILP approaches. This showed that, in a combined heat and power (CHP) system, the optimized solar field produced around 55% of user annual demand.…”

Section: Optimization Issues Of State-of-the-art District Heating Network and Tools Used To Address The Problemmentioning

confidence: 99%

“…The storage is therefore broken down into 91.25 small equal volumes called V part , and we assume that storage use on one of the typical days is the same as for the other 91.25 times. The terms V hot and V cold from Equations ( 26)- (29) become V hot,part and V cold,part with V hot,part + V cold,part = V part and V total = 91.25 × V part . According to Equations ( 26)- (29), when moving from one typical day to another (i.e., from one season to another) the state of the storage at the end of a season is retained at the start of the next.…”

Section: Storage Modelmentioning

confidence: 99%

“…The terms V hot and V cold from Equations ( 26)- (29) become V hot,part and V cold,part with V hot,part + V cold,part = V part and V total = 91.25 × V part . According to Equations ( 26)- (29), when moving from one typical day to another (i.e., from one season to another) the state of the storage at the end of a season is retained at the start of the next.…”

Section: Storage Modelmentioning

confidence: 99%

“…polynomial CapEx stor = a stor V 2 stor + b stor V stor + c stor V stor (29) logarithmic CapEx stor = (a stor log(V stor ) + b stor ) V stor (30) exponential CapEx stor = a stor exp − V stor b stor + c stor V stor (31) power CapEx stor = a stor V stor b stor V stor (32) Different tests were carried out before ultimately choosing the exponential approach (31) (a stor = EUR 1918.45/m 3 , b stor = 309.77 m 3 and c stor = EUR 117.62/m 3 ) to calculate the installation costs (CapEx) while keeping a reasonable degree of precision, as can be seen in Figure 7. The exponential approach has the advantage of being able to take into account storage larger than 10,000 m 3 because the costs converge to the value of c stor .…”

Section: Economical Modelmentioning

confidence: 99%

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A Dynamic Optimization Tool to Size and Operate Solar Thermal District Heating Networks Production Plants

et al. 2021

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The aim of the ISORC/OPTIMISER project is to increase and improve the use of solar thermal energy in district heating networks. One of the main tasks of the project is to develop an optimization tool for the sizing and operation of a solar district heating network. This is the first optimization tool using an open-source interface (Julia, JuMP) and solver (Ipopt) to solve nonlinear problems. This paper presents the multi-period optimization problem which is implemented to consider the dynamic variations in a year, represented by four typical days, with an hourly resolution. The optimum is calculated for a total duration of 20 years. First, this paper presents the modeling of the different components of a solar district heating network production plant: district network demand, storage and three sources, i.e., a fossil (gas) and two renewable (solar and biomass) sources. In order to avoid prohibitive computational time, the modeling of sources and storage has to be fairly simple. The multi-period optimization problem was formulated. The chosen objective function is economic: The provided economic model is accurate and use nonlinear equations. Finally the formulated problem is a nonlinear Programming problem. Optimization of the studied case exhibits consistent operating profiles and design. A comparison is made of different types of storage connection at the production site, highlighting the relevance of placing the storage at the solar field outlet. The optimum configuration supplies 49% of demand using solar energy, achieving a renewable rate of 69% in combination with the biomass boiler.

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Optimization framework for evaluating urban thermal systems potential

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et al. 2023

Energy

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A Comparison of Different District Integration for a Distributed Generation System for Heating and Cooling in an Urban Area

Cited by 12 publications

References 29 publications

A Review of Small–Medium Combined Heat and Power (CHP) Technologies and Their Role within the 100% Renewable Energy Systems Scenario

A Review of Small–Medium Combined Heat and Power (CHP) Technologies and Their Role within the 100% Renewable Energy Systems Scenario

A Dynamic Optimization Tool to Size and Operate Solar Thermal District Heating Networks Production Plants

Optimization framework for evaluating urban thermal systems potential

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