Modelling of organic Rankine cycle power systems in off-design conditions: An experimentally-validated comparative study

Dickes, Rémi; Dumont, Olivier; Daccord, Rémi; Quoilin, Sylvain; Lemort, Vincent

doi:10.1016/j.energy.2017.01.130

Cited by 69 publications

(20 citation statements)

References 24 publications

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“…By accounting for the most influent physical phenomena in the expansion process with a limited number of parameters, this model demonstrates a good ability to extrapolate the expander performance out of the calibration dataset [25,31] while maintaining low computational times. One advantage of this approach is its common framework to simulate different types of technologies (scroll, screw, piston, vane, etc.)…”

Section: Semi-empirical Modelmentioning

confidence: 99%

Experimental investigation and optimal performance assessment of four volumetric expanders (scroll, screw, piston and roots) tested in a small-scale organic Rankine cycle system

Dumont

Parthoens

Dickes

et al. 2018

Energy

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102

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Keywords:Modeling Experimental Scroll Screw Piston Roots Volumetric Expander ORC a b s t r a c tThe aim of this paper is to facilitate the selection of the expander for a small-scale organic Rankine cycle based on an experimental comparison of a piston, a screw, a scroll and a roots expander. First, based on a literature review, a comparison between these four technologies of volumetric expansion machines is performed. Afterward, four displacement expanders [2e4 kW] are tested on two similar small-scale ORC unit with fluid R245fa. The maximum effective isentropic efficiencies measured are 53% for the piston expander and the screw expander, 76% for the variable-speed scroll and 48% for the roots machine. However, these performances do not reflect the highest efficiencies achievable by each expander: the test-rig presents experimental limitations in terms of mass flow rate and pressure drop (among others) that restricts the achievable operating conditions. The calibration of semi-empirical models based on the measurements allows to overcome this issue and to predict the isentropic efficiency in optimal conditions despite the limitations of the test-rigs. Based on experimental results, extrapolated prediction of the semi-empirical model and practical considerations, some guidelines are drawn to help the reader to select properly a volumetric expander.

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Section: Semi-empirical Modelmentioning

confidence: 99%

Experimental investigation and optimal performance assessment of four volumetric expanders (scroll, screw, piston and roots) tested in a small-scale organic Rankine cycle system

Dumont

Parthoens

Dickes

et al. 2018

Energy

Self Cite

102

View full text Add to dashboard Cite

show abstract

“…Such a model receives as inputs the working fluid type, the inlet temperature and mass flow rate of the source and sink fluids, the rotational speeds of the pump and expander, and the condenser exit subcooling or the total working fluid charge in the system. A truly mechanistic model is charge-sensitive, meaning the total refrigerant charge is known, but the condenser exit subcooling is determined by the ORC operation [5]. In fact, if the condenser exit subcooling is fixed within the simulation, an assumption is made regarding the system state, which is not known in a real system.…”

Section: Definition Of a Mechanistic Model For Orc Systemmentioning

confidence: 99%

“…However, in the vast majority of stationary applications (e.g., solar thermal power, geothermal, waste heat recovery, and combined heat and power), the heat source and heat sink conditions are subjected to fluctuations and the ORC systems often operate at part-load or off-design conditions. To this end, numerical and experimental studies on off-design ORC performance have been published in the scientific literature, as outlined by Dickes et al [5]. Similar to vapor compression systems, ORC performance is sensitive to working fluid charge and an incorrect charge level affects the system performance, especially under part-load conditions.…”

Section: Introductionmentioning

confidence: 99%

Effects of the Working Fluid Charge in Organic Rankine Cycle Power Systems: Numerical and Experimental Analyses

Ziviani¹,

Dickes²,

Lemort³

et al. 2018

Organic Rankine Cycle Technology for Heat Recovery

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It is well known that organic Rankine cycle (ORC) power systems often operate in conditions differing from the nominal design point due to variations of the heat source and heat sink conditions. Similar to a vapor compression cycle, the system operation (e.g., subcooling level, pump cavitation) and performance (e.g., heat exchanger effectiveness) of an ORC are affected by the working fluid charge. This chapter presents a discussion of the effects of the charge inventory in ORC systems. In particular, both numerical and experimental aspects are presented. The importance of properly predicting the total amount of working fluid charge for optimizing design and off-design conditions is highlighted. Furthermore, an overview on state-of-the-art modeling approaches is also presented.

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“…The ORC have been investigated on its working fluid screening [12,13], performance optimization [14,15] and dynamic simulation [16,17] in the past several decades. Meanwhile, medium-large-scale ORC prototypes and engineering cases have been carried out [18][19][20][21]. However, the expensive design and manufacture costs of expander imposes the largest restriction on commercial application of the small-scale ORC system, investment is much larger than 1500 $ per kW.…”

Section: Introductionmentioning

confidence: 99%

Design and experimental research on the combined flash-binary geothermal power generation system driven by low-medium temperature geothermal system

et al. 2020

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To match for the different temperature of the geothermal resource and strengthen the flexibility of organic Rankine cycle, a variable capacity power generation superstructure based on flash and organic Rankine cycle for geothermal energy was proposed. A combined flash-binary experimental prototype is newly established to investigate thermodynamic performance both on system and equipment in this paper. Pressured hot water is adopted as the extensive worldwide existed hydrothermal geothermal resource, eliminating the influence of the used heat transfer oil on evaporating process. The experimental results show that there is an optimal mass-flow rate of R245fa under the condition of different heat source temperature. Flash and binary power subsystem dominate the flash-binary power system, respectively, when the heat source temperature is 120 ℃ and 130 ℃. The isotropic efficiency of modified compressor just between 0.2 and 0.25. The power output of per ton geofluid are 0.78 kWh/t and 1.31 kWh/t, respectively, when the heat source temperature are 120 ℃ and 130 ℃. These results will predict the operation data of flash-binary power plant driven by the low-medium temperature geothermal water for construction in western of China.

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Modelling of organic Rankine cycle power systems in off-design conditions: An experimentally-validated comparative study

Cited by 69 publications

References 24 publications

Experimental investigation and optimal performance assessment of four volumetric expanders (scroll, screw, piston and roots) tested in a small-scale organic Rankine cycle system

Experimental investigation and optimal performance assessment of four volumetric expanders (scroll, screw, piston and roots) tested in a small-scale organic Rankine cycle system

Effects of the Working Fluid Charge in Organic Rankine Cycle Power Systems: Numerical and Experimental Analyses

Design and experimental research on the combined flash-binary geothermal power generation system driven by low-medium temperature geothermal system

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