Overview
ABSTRACT
An absorption cycle integrated with a turbine allows the co-production of cold and electricity. This technology is very promising for its ability to harness low temperature heat sources more efficiently than separate production with simple thermodynamic cycles. The development of a detailed model of the complete cycle makes it possible to evaluate the performance achievable and the interest of this technology. Based on the numerical studies, a pilot plant was developed and tested on a laboratory scale to better understand the functioning of the cycle and the design challenges. The results will be very important for future development and scale-up of the technology for use in application to be identified.
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Read the articleAUTHORS
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Simone BRACCIO: Research engineer - CEA Grenoble LITEN/DTCH, laboratory LOCIE UMR 5271 CNRS, University Savoie Mont-Blanc
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Hai Trieu PHAN: Research engineer - CEA Grenoble LITEN/DTCH
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Nicolas TAUVERON: Research engineer - CEA Grenoble LITEN/DTCH
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Nolwenn LE PIERRÈS: University Professor - LOCIE Laboratory UMR 5271 CNRS, Savoie Mont-Blanc University
INTRODUCTION
Given the ever-increasing global demand for energy, and the attention being paid to environmental issues and climate change, research is increasingly being carried out into new, more efficient cooling and electricity production technologies based on renewable or recovered sources. In this context, absorption systems are well suited to harnessing low-temperature energy for cold production. The advantage of these machines is that mechanical compression is replaced by thermochemical compression, using heat as the energy source. In addition to the control systems, the main electricity input is for a pump, but this is around 10 to 30 times less than that required for a compressor. Another advantage of absorption machine technology is that it can produce cold using well-known refrigerants such as ammonia or water, which are not harmful to the ozone layer and do not emit greenhouse gases. Absorption cooling systems have until now been niche technologies, but the market is growing with a reduction in their costs, which were halved between 2007 and 2016 according to a European study. Such systems are particularly promising in two areas: the recovery of industrial waste heat, and the use of renewable heat sources, especially in solar air-conditioning where the solar resource is well suited to the cooling requirement.
Although characterized by a low level of technological maturity (TRL 3-4 on a maturity scale of up to 9), the co-production, within the same cycle, of electricity and cooling from a low-temperature thermal source is the subject of numerous studies. Such a system would make it possible to increase the energy efficiency of the overall system and to mutualize certain components. This article focuses on a combined system for parallel production of cooling and electricity from a low-temperature heat source. The study is based on an experimental prototype of a water/ammonia absorption chiller with a thermal power of 10 kW at the generator, in which a turbine is integrated. A 1D model of the turbine, calibrated on CFD (Computational Fluid Dynamics) simulations, is integrated into a validated model of the absorption machine and used to study the interactions between the turbine and the cycle containing it. The constraints imposed by the turbomachine on the cycle are highlighted, and solutions for increasing the system's flexibility are proposed.
The analyses carried out have enabled us to define the cycle's operating range and study its performance. These results, together with feedback from the prototype, will be very important for the future development of a full-scale demonstrator for an application yet to be identified.
A table of acronyms, notations and symbols is provided at the end of the article....
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KEYWORDS
absorption | Combined cycle | Ammonia/water | Axial turbine
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Industrial cooling
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NH3/H2O absorption cycle for co-generation of cooling and electricity
Bibliography
- (1) - Mission Innovation. - http://mission-innovation.net/ (2020).
- (2) - EUROPEAN COMMISSION - Clean energy for all Europeans. - Euroheat Power (English Ed.),...
Regulations
Regulation (EU) No 517/2014 of the European Parliament and of the Council of 16 April 2014 on fluorinated greenhouse gases and repealing Regulation (EC) No 842/2006 (OJEU No L. 150 of 20 May 2014) https://climate.ec.europa.eu/eu-action/fluorinated-greenhouse-gases/eu-legislation-control-f-gases_en...
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