Your search keyword '"Systèmes hybrides"' showing total 3 results

1. Performance investigation of hybrid adsorption-compression refrigeration system accompanied with phase change materials − Intermittent characteristics.

Author

Gado, Mohamed G., Ookawara, Shinichi, Nada, Sameh, and Hassan, Hamdy

Subjects

*PHASE change materials, *HYBRID systems, *SILICA gel, *ELECTRIC power, *TEMPERATURE measuring instruments, *ATMOSPHERIC temperature

Abstract

• Intermittent characteristics of hybrid adsorption-compression systems are examined. • The hybrid system under intermittent mode exhibits a daily energy saving of 37%. • The system performance under intermittent mode outperforms the continuous operation. • PCM has significantly reduces the compressor on-time operations. • PCM is incorporated into the system to curtail the cyclic temperature fluctuations. In the current study, intermittent characteristics of hybrid adsorption-compression refrigeration systems are evaluated, notably for cold storerooms. This hybrid system utilizes ultra low-grade heat (65 °C) and works with natural refrigerants. Herein, the dual-bed adsorption system operates with a working pair of silica gel/water (R718), while isobutane (R600a) is adopted for the compression system. Phase change material (PCM) is additionally incorporated to prolong the compressor off durations and improve the stabilization of the air temperature inside the cold storeroom. Mathematical modeling of the proposed systems is established using MATLAB/SIMULINK framework and validated with relevant literature. An examination of the temporal behavior of the hybrid system's leading indicators such as temperature profiles, cooling capacity, COP, electric power, and electricity demand based on the intermittent characteristics has been conducted and compared against the baseline system. The results demonstrate that the energy saving of the hybrid system during the intermittent operation mode (37%) outperforms the continuous operation mode (31.63%). Also, the hybrid system at the steady-state stage attains COP of ∼4 compared to ∼2.3 for the baseline system. However, incorporating PCM into the hybrid system abates the air temperature fluctuation inside the cold storeroom, diminishes the cyclic operations, and reduces the on-time ratio by 24.1% compared to the baseline system (34.8%) while slightly reducing the system COP. The utilization of hybrid refrigeration systems accompanied by PCM has significant profit over conventional compression systems in the market. [ABSTRACT FROM AUTHOR]

Published

2022

2. Wrapping DEVS de modèles IP dans MECSYCO pour la co-simulation de systèmes cyber-physiques.

Author

Camus, Benjamin, Vaubourg, Julien, Paris, Thomas, Presse, Yannick, Bourjot, Christine, Ciarletta, Laurent, and Chevrier, Vincent

Abstract

The modeling and simulation of cyber-physical systems (as smart-grids) are becoming an essential step of their construction process. One central challenge is to integrate in a consistent way each domain and point of view on the target system, each already having its own formalisms and modeling tools. This article presents the benefits of a DEVS wrapping based cosimulation platform (MECSYCO) in terms of integration of the heterogeneity of models and simulators: formalisms, time and data representations, software, etc. The platform provides modularity in the modeling and simulation process: incrementally, simulators, exchanges, etc. We show how we have integrated tools like NS3 and OMNET++/INET (reference tools for IP network modeling), or simulation standard such as FMU in our platform and how they can be used in cosimulations. A hybrid co-simulation use case is presented to illustrate our proposal. [ABSTRACT FROM AUTHOR]

Published

2018

3. Dynamics of coupled multimode and hybrid optomechanical systems

Author

Heinrich, Georg, Ludwig, Max, Wu, Huaizhi, Hammerer, K., and Marquardt, Florian

Subjects

*OPTOMECHANICS, *COHERENT states, *QUANTUM optics, *QUANTUM theory, *PHOTONICS, *HYBRID systems

Abstract

Abstract: Recent experimental developments have brought into focus optomechanical systems containing multiple optical and mechanical modes interacting with each other. Examples include a setup with a movable membrane between two end-mirrors and “optomechanical crystal” devices that support localized optical and mechanical modes in a photonic crystal type structure. We discuss how mechanical driving of such structures results in coherent photon transfer between optical modes, and how the physics of Landau–Zener–Stueckelberg oscillations arises in this context. Another area where multiple modes are involved are hybrid systems. There, we review the recent proposal of a single atom whose mechanical motion is coupled to a membrane via the light field. This is a special case of the general principle of cavity-mediated mechanical coupling. Such a setup would allow the well-developed tools of atomic physics to be employed to access the quantum state of the ‘macroscopic’ mechanical mode of the membrane. [Copyright &y& Elsevier]

Published

2011