Automation and Electrical Actuation of a Compressed Air Energy Storage Installation

Borzea, Claudia; HĂRĂGUȚĂ, Cristinel; Sávescu, A.; GĂZDAC, Alexandru

doi:10.36801/apme.2019.1.2

Cited by 2 publications

(1 citation statement)

References 8 publications

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“…Both the maximum power and the stabilization power (Figure 5 above) were significantly higher than the ones obtained during bench tests without thermal recovery tank, even with preheating oil with a heating resistance [9,10]. In the tables below are given the parameters ranges (minimum and maximum values), measured during commissioning tests.…”

Section: Experimental and Theoretical Resultsmentioning

confidence: 99%

Compressed air energy storage facility with water tank for thermal recovery

et al. 2020

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The paper presents the prototype of the first Romanian Compressed Air Energy Storage (CAES) installation. The relatively small scale facility consists of a twin-screw compressor, driven by a 110 kW threephase asynchronous motor, which supplies pressurized air into a 50m3 reservoir, of 20 bar maximum pressure. The air from the vessel is released into a twin-screw expander, whose shaft spins a 132 kW electric generator. The demonstrative model makes use of a 5m3 water tank acting as heat transfer unit, for minimising losses and increasing efficiency and the electric power generated. Air compression and decompression induce energy losses, resulting in a low efficiency, mainly caused by air heating during compression, waste heat being released into the atmosphere. A similar problem is air cooling during decompression, lowering the electric power generated. Thus, using a thermal storage unit plays an essential role in the proper functioning of the facility and in generating maximum electric power. Supervisory control and data acquisition is performed from the automation cabinets. During commissioning tests, a constant stable power of around 50 kW with an 80 kW peak was recorded.

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Section: Experimental and Theoretical Resultsmentioning

confidence: 99%

Compressed air energy storage facility with water tank for thermal recovery

et al. 2020

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Asynchronous Three-Phase Machine Driven as Generator by a Twin-Screw Expander

Borzea

Sávescu

Vlăducă

et al. 2021

APME

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The paper presents the functioning regimes of a 132 kW asynchronous three-phase machine, used for the expander-generator system in a compressed air energy storage facility. The installation consists of a 110 kW twin-screw electro-compressor, which supplies pressurized air up to ~16 bar into a 50 cubic meters storage vessel. The compressed air is afterwards released from the reservoir into expander’s inlet, spinning its shaft. When the expander’s shaft spins the electric machine over its synchronous speed, this one enters in generator mode, supplying electric power into the grid. Two power analysers installed on the automation control cabinet monitor the generated/absorbed power and the power supplied/consumed by the system from the grid. Using the data acquired by means of PLC during commissioning tests, we plotted the power curves, differential pressure and significant temperatures, as well as the electric machine’s speed.

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Automation and Electrical Actuation of a Compressed Air Energy Storage Installation

Cited by 2 publications

References 8 publications

Compressed air energy storage facility with water tank for thermal recovery

Compressed air energy storage facility with water tank for thermal recovery

Asynchronous Three-Phase Machine Driven as Generator by a Twin-Screw Expander

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