New insights in twin screw expander performance for small scale ORC systems from 3D CFD analysis

Papeš, Iva; Degroote, Joris; Vierendeels, Jan

doi:10.1016/j.applthermaleng.2015.08.034

Cited by 66 publications

(36 citation statements)

References 17 publications

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“…• The heat transfer between the working fluid and the rotor and between the casing and the ambient is not included 105 in the model, since it was also not included in the CFD model in [19]. This simplification resulted in good agreement between CFD and experiments in [22] for a compressor.…”

Section: Thermodynamic Multi-chamber Modelmentioning

confidence: 94%

“…• If the chamber is connected to the outlet port, the pressure in the working chamber becomes equal to the discharge pressure.This assumption will affect the results (since it assumes that the pressure in the outlet port is constant) but this influence is small since the pressure in the outlet port is not affected by high pressure pulsations as is the case in the inlet port shown by CFD calculations in [19].…”

mentioning

confidence: 99%

“…The validation of the Aungier Redlich-Kwong EoS for the range of operating conditions used in this study is presented in [19]. …”

mentioning

confidence: 99%

“…For this the authors use the results of 3D CFD analysis of the twin screw expander presented in [19].…”

mentioning

confidence: 99%

“…Mass flow rates through the clearances that are forming leakage paths have a significant effect on the performance of screw machines. Three different clearance gaps were evaluated in the CFD analysis performed by the authors in [19] namely the tip, the sealing and the blowhole leakage. These leakage paths are included in the developed 90 mathematical model and are shown in figure 1.…”

mentioning

confidence: 99%

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Development of a thermodynamic low order model for a twin screw expander with emphasis on pulsations in the inlet pipe

Papeš

Degroote

Vierendeels

2016

Applied Thermal Engineering

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A twin screw expander is a positive displacement machine used in various applications of waste heat recovery. The performance of this machine is influenced by internal leakages, gas pulsations formed in the inlet pipe and the properties of the refrigerant. In this paper a multi-chamber mathematical model of a twin screw expander is presented to predict its performance. From the mass and energy conservation laws, differential equations are derived which are then solved together with the appropriate Equation of State (EoS) in the instantaneous control volumes. In order to calculate the mass flow rates through leakage paths more accurately, flow coefficients used in the converging nozzle model were derived from 3D Computational Fluid Dynamic (CFD) calculation. Due to high gas pulsation levels at the inlet port, a coupling with a 3D CFD inlet pipe model is introduced in order to better predict throttling losses. The maximal deviation between predictions by the developed model and 3D CFD calculations of the complete machine is around 5% for the mass flow rate and the power output.

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Section: Thermodynamic Multi-chamber Modelmentioning

confidence: 94%

mentioning

confidence: 99%

“…The validation of the Aungier Redlich-Kwong EoS for the range of operating conditions used in this study is presented in [19]. …”

mentioning

confidence: 99%

“…For this the authors use the results of 3D CFD analysis of the twin screw expander presented in [19].…”

mentioning

confidence: 99%

mentioning

confidence: 99%

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Development of a thermodynamic low order model for a twin screw expander with emphasis on pulsations in the inlet pipe

Papeš

Degroote

Vierendeels

2016

Applied Thermal Engineering

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Energy performance and numerical optimization of a screw expander–based solar thermal electricity system in a wide range of fluctuating operating conditions

2019

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Summary This paper provides fundamental principles to study the thermodynamic performance of a new screw expander–based solar thermal electricity plant. While steam turbines are generally used in direct steam generation solar systems without admitting fluid in two‐phase conditions, steam screw expanders, as volumetric machines, can convert thermal to mechanical energy also by expanding liquid‐steam mixtures without a decline in efficiency. In effect, steam turbines are not as competitive as screw expanders when the net power is smaller than 2 MW and for low‐grade heat sources. The solar electricity generation system proposed in this paper is based on the steam Rankine cycle: Water is used as both working fluid and storage, parabolic trough collectors are used as a thermal source, and screw expanders are used as power machines. Since screw expanders can operate at off‐design working conditions in several situations when installed in direct steam generation solar plants, studying expander performance under fluctuating working situations is a crucial issue. The main aim of the present paper is to establish a thermodynamic model to study the energetic benefits of the proposed power system when off‐design operating conditions and variable solar radiation occur. This entails, first and foremost, developing overexpansion and underexpansion numerical models to describe the polytropic expansion phase, which considers all the losses affecting performance of the screw expander under real operating conditions. To assess the best operating conditions and maximum efficiency of the whole power system at part‐load working conditions under fluctuating solar radiations, parametric optimization is then improved in a wide range of variable working conditions, assuming condensation pressures of water increasing from 0.1 to 1 bar, under an evaporation temperature rising from 170°C to 300°C.

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A novel method for rotor profile optimization of high temperature screw expanders employed in waste heat recovery systems

et al. 2021

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High temperature expanders have always been employed in industrial waste heat recovery systems, where twin-screw expanders were frequently adopted.However, the significant thermal deformation of rotors contributes to much technical difficulty on the designation and manufacturing of high temperature twin-screw expanders. The profile should be optimized with consideration of its thermal deformation in high temperature working conditions. In this article, a novel method for twin-screw expander profile optimization is developed.The thermal deformation of rotors is considered with meshing pair rules and interlobe clearance presetting. Theoretical analysis on interlobe clearance is made any steam inlet temperature from 20 C to 400 C, while experimental facility was built to figure out its reliability at high temperature. The optimized profile proved the effectiveness of this method. The clearance decreases significantly, decreasing from 1.28 mm at the working temperature of 20 C to 0.16 mm at 400 C. The testing results illustrated that the significant thermal deformation of rotors causes much interlobe abrasion once the operating temperature reached 400 C. With clearance of 0.1 mm and the radius correction angle of 0.0758 , the screw expander was proved to be reliably working at 400 C.

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New insights in twin screw expander performance for small scale ORC systems from 3D CFD analysis

Cited by 66 publications

References 17 publications

Development of a thermodynamic low order model for a twin screw expander with emphasis on pulsations in the inlet pipe

Development of a thermodynamic low order model for a twin screw expander with emphasis on pulsations in the inlet pipe

Energy performance and numerical optimization of a screw expander–based solar thermal electricity system in a wide range of fluctuating operating conditions

A novel method for rotor profile optimization of high temperature screw expanders employed in waste heat recovery systems

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