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Abstract
The spread of the organic rankine cycle applications has driven researchers and companies to focus on the improvement of their performance. In small to medium-sized plants, the expander is the component that has typically attracted the most attention. One of the most used types of machine in this scenario is the scroll. Among the other methods, numerical analyses have been increasingly exploited for the investigation of the machine’s behaviour. Nonetheless, there are major challenges for the successful application of computational fluid dynamics (CFD) to scrolls. Specifically, the dynamic mesh treatment required to capture the movement of working chambers and the nature of the expanding fluids require special care. In this work, a mesh generator for scroll machines is presented. Given few inputs, the software described provides the mesh and the nodal positions required for the evolution of the motion in a predefined mesh motion approach. The mesh generator is developed ad hoc for the coupling with the open-source CFD suite OpenFOAM. A full analysis is then carried out on a reverse-engineered commercial machine, including the refrigerant properties calculations via CoolProp. It is demonstrated that the proposed methodology allows for a fast simulation and achieves a good agreement with respect to former analyses.
Highlights
Scroll compressors have been extensively employed in air conditioning and refrigeration since the 1980s
Scroll expanders are frequently adopted in micro-Organic Rankine Cycles (ORCs) with power outputs up to 2 kW, as described in different literature works reporting experimental tests
A new meshing tool developed in C++ has been proposed. The capability of this tool to manage a fully 3D computational fluid dynamics (CFD) simulation is proven by the analysis of a commercial scroll compressor in an open-source CFD environment, i.e., OpenFOAM
Summary
Scroll compressors have been extensively employed in air conditioning and refrigeration since the 1980s. Their success is mostly related to a low level of noise and vibrations, together with a small number of moving parts and a compact design. The scroll expander is generally characterized by higher pressure ratios and efficiency and by lower flow rates and rotational speeds [2]. Scroll expanders are frequently adopted in micro-ORCs with power outputs up to 2 kW, as described in different literature works reporting experimental tests. Wang et al [5] have tested a scroll expander with R134a over a wide range of rotational speeds, reaching a shaft work output close to
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