Your search keyword '"Szabłowski, Łukasz"' showing total 2 results

1. Selecting Cycle and Design Parameters of a Super Critical CO 2 Cycle for a 180 kW Biogas Engine.

Author

Milewski, Jarosław, Szczęśniak, Arkadiusz, Lis, Piotr, Szabłowski, Łukasz, Dybiński, Olaf, Futyma, Kamil, Sieńko, Arkadiusz, Olszewski, Artur, Sęk, Tomasz, and Kryłłowicz, Władysław

Subjects

CARBON dioxide, HEAT recovery, BIOGAS, THERMODYNAMIC cycles, HEATING

Abstract

The objective of this paper was to study the sCO2 cycle as a waste heat recovery system for a 180 kW biogas engine. The research methodology adopted was numerical simulations through two models built in different programs: Aspen HYSYS and GT Suite. The models were used to optimize the design and thermodynamic parameters of a CO2 cycle in terms of system power, system efficiency, expander, and compressor efficiency. Depending on the objective function, the sCO2 cycle could provide additional power ranging from 27.9 to 11.3 kW. Based on the calculation performed, "Recuperated cycle at maximum power" was selected for further investigation. The off-design analysis of the system revealed the optimum operating point. The authors designed the preliminary dimensions of the turbomachinery, i.e., the rotor dimension is 16 mm, which will rotate at 100,000 rpm. [ABSTRACT FROM AUTHOR]

Published

2024

2. Determination of Thermocline Heat Transfer Coefficient by Using CFD Simulation.

Author

Szczęśniak, Arkadiusz, Milewski, Jarosław, Dybiński, Olaf, Futyma, Kamil, Skibiński, Jakub, Martsinchyk, Aliaksandr, and Szabłowski, Łukasz

Subjects

HEAT storage, ENERGY storage, HEAT transfer coefficient, HEAT transfer, COMPUTATIONAL fluid dynamics, STORAGE tanks, HEAT losses, HOT water

Abstract

This article deals with a thermal energy storage system in the form of a water tank with a thermocline. The well-known thermocline phenomenon is modeled using computational fluid dynamics (CFD). However, the reservoir model proposed in this article is zero-dimensional. This is due to the fact that the aim of this article is to build a mathematical model that will be more useful in mathematical models of complex energy systems in which a hot water tank is one of many elements of the system. In such a zero-dimensional mathematical model, the hot water tank will be modeled using equations describing heat transfer, and the thermocline itself will be treated as a heat transfer surface with known dimensions and heat transfer coefficient. A novelty of this paper is that it addresses heat loss across the thermocline as defined in this manner. A CFD model of a thermal storage tank is created, validated with available experimental data, and used to obtain the heat transfer coefficient U. The resulting value is then analyzed quantitatively and qualitatively and the changes in the thickness of the thermocline are accounted for in the equation. The results from this groundbreaking work can be used to analyze heat storage in the form of thermocline water tanks at the level of system modeling, e.g., for the purpose of configuring the structure of other devices and control systems. [ABSTRACT FROM AUTHOR]

Published

2023