Experimental and Numerical Study of Supersonic Non-ideal Flows for Organic Rankine Cycle Applications

Robertson, Miles; Newton, Peter; Chen, Tao; Costall, Aaron; Martinez-Botas, Ricardo

doi:10.1115/1.4046758

Cited by 9 publications

(6 citation statements)

References 12 publications

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“…Amongst these so-called nozzlefitted facilities is the Test Rig for Organic VApors (TROVA) (Spinelli et al, 2013) at the Laboratory of Compressible Fluid-dynamics for Renewable Energy Applications (CREA Lab) of Politecnico di Milano, where all the experimental campaigns concerning the present work were carried out. Other plants of this kind are the ORCHID (Head et al, 2016) at TU Delft, the CLOWT (Reinker et al, 2017) at Muenster University of Applied Sciences and the dense-gas blowdown facility at Imperial College London (Robertson et al, 2020). Several turbine-fitted facilities mainly devoted to performance measurement of the different components and of the overall thermodynamic cycle also exist, such as the LUT micro-ORC test rig at Lappeenranta -Lahti University of Technology (Turunen-Saaresti et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Shock losses and Pitot tube measurements in non-ideal supersonic and subsonic flows of Organic Vapors

Conti

Fusetti

Spinelli

et al. 2023

Energy

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Section: Introductionmentioning

confidence: 99%

Shock losses and Pitot tube measurements in non-ideal supersonic and subsonic flows of Organic Vapors

Conti

Fusetti

Spinelli

et al. 2023

Energy

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“… 2017 ) at Muenster University of Applied Sciences and the dense gas blowdown facility at Imperial College London (Robertson et al. 2020 ).…”

Section: Introductionmentioning

confidence: 99%

“…Among these, so-called nozzlefitted facilities is the Test Rig for Organic VApors (TROVA) (Spinelli et al 2013) at the Laboratory of Compressible fluid dynamics for Renewable Energy Applications (CREA Lab) of Politecnico di Milano, where all the experimental campaigns concerning the present work were carried out. Other plants of this kind are the ORCHID (Head et al 2016) at TU Delft, the CLOWT (Reinker et al 2017) at Muenster University of Applied Sciences and the dense gas blowdown facility at Imperial College London (Robertson et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Shock loss measurements in non-ideal supersonic flows of organic vapors

et al. 2022

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This paper presents the first ever direct measurements of total pressure losses across shocks in supersonic flows of organic vapors in non-ideal conditions, so in the thermodynamic region close to the liquid–vapor saturation curve and the critical point where the ideal gas law is not applicable. Experiments were carried out with fluid siloxane MM (hexamethyldisiloxane, C$$_6$$ 6 H$$_{18}$$ 18 OSi$$_2$$ 2 ), commonly employed in medium-/high-temperature organic Rankine cycles (ORCs), in the Test Rig for Organic VApors (TROVA), a blowdown wind tunnel at the Laboratory of Compressible fluid dynamics for Renewable Energy Applications (CREA lab) of Politecnico di Milano. A total pressure probe was inserted in superheated MM vapor flow at Mach number $$\sim 1.5$$ ∼ 1.5 with total conditions in the range $$215-230~^\circ \hbox {C}$$ 215 - 230 ∘ C and $$2-12~\hbox {bar}$$ 2 - 12 bar at varying levels of non-ideality, with a compressibility factor evaluated at total conditions between $$Z_\text {T}=0.68-0.98$$ Z T = 0.68 - 0.98 . These operating conditions are representative of the first-stage stator of ORC turbines. Measured shock losses were compared with those calculated from pre-shock quantities by solving conservation equations across a normal shock, with differences always below $$2 \%$$ 2 % attesting a satisfactory reliability of the implemented experimental procedure. An in-depth analysis was then carried out, highlighting the direct effects of non-ideality on shock intensity. Even at the mildly non-ideal conditions with $$Z_\text {T}\gtrsim 0.70$$ Z T ≳ 0.70 considered here, non-ideality was responsible for a significantly stronger shock compared to the ideal gas limit at same pre-shock Mach number, with differences as large as $$6\%$$ 6 % . Graphical abstract

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“…Given this, the design of such machines is particularly critical, also considering that turbine efficiency impacts the economic competitiveness of the ORC technology. Current computational tools are based on advanced CFD codes ( [7,8,9,10,11]) embedding state-of-the-art thermodynamic models ( [12,13]), but experimental data are only recently becoming available in literature for comparison and verification ( [14,4,5,15]). This is mainly due to the peculiar features of organic fluid flows, as the high temperature, the vicinity to the saturation curve and to the thermal stability limits, which challenge the success of ad-hoc experimental campaigns.…”

Section: Introductionmentioning

confidence: 99%

Experimental characterization of nozzle flow expansions of siloxane MM for ORC turbines applications

Cammi

Conti

Spinelli

et al. 2021

Energy

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Experimental and Numerical Study of Supersonic Non-ideal Flows for Organic Rankine Cycle Applications

Cited by 9 publications

References 12 publications

Shock losses and Pitot tube measurements in non-ideal supersonic and subsonic flows of Organic Vapors

Shock losses and Pitot tube measurements in non-ideal supersonic and subsonic flows of Organic Vapors

Shock loss measurements in non-ideal supersonic flows of organic vapors

Experimental characterization of nozzle flow expansions of siloxane MM for ORC turbines applications

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